Method and apparatus for transmitting uplink control information in wireless communication system

ABSTRACT

A communication technique for combining a 5G communication system for supporting a higher data rate after 4G system with IoT technology includes transmitting configuration information of one or more serving cells that operate in an unlicensed band to a terminal, transmitting information indicating that an uplink control channel and an uplink data channel can be simultaneously transmitted to the terminal, determining whether the terminal is configured to transmit at least one of data and the uplink control information through the uplink data channel in at least one of a licensed band and the unlicensed band, and receiving the uplink control information in at least one of the licensed band and the unlicensed band on the basis of the determination, wherein the configuration information includes unlicensed-band uplink control channel configuration information for configuring the uplink control channel in one of the serving cells that operate in the unlicensed band.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of application Ser. No. 15/466,766,filed Mar. 22, 2017, which claims priority to Korean Application No.10-2016-0034104, filed, Mar. 22, 2016, and Korean Application No.10-2016-0102770, filed Aug. 12, 2016, the entire disclosures of whichare hereby incorporated by reference.

BACKGROUND 1. Field

The present disclosure relates to a method and an apparatus fortransmitting uplink control information and data efficiently in a mobilecommunication system that operates in an unlicensed band or in a mobilecommunication system that requires channel sensing (orlisten-before-talk).

2. Description of Related Art

To meet the demand for wireless data traffic having increased sincedeployment of 4G communication systems, efforts have been made todevelop an improved 5G or pre-5G communication system. Therefore, the 5Gor pre-5G communication system is also called a ‘Beyond 4G Network’ or a‘Post LTE System’. The 5G communication system is considered to beimplemented in higher frequency (mmWave) bands, e.g., 60 GHz bands, soas to accomplish higher data rates. To decrease propagation loss of theradio waves and increase the transmission distance, the beamforming,massive multiple-input multiple-output (MIMO), Full Dimensional MIMO(FD-MIMO), array antenna, an analog beam forming, large scale antennatechniques are discussed in 5G communication systems. In addition, in 5Gcommunication systems, development for system network improvement isunder way based on advanced small cells, cloud Radio Access Networks(RANs), ultra-dense networks, device-to-device (D2D) communication,wireless backhaul, moving network, cooperative communication,Coordinated Multi-Points (CoMP), reception-end interference cancellationand the like. In the 5G system, Hybrid FSK and QAM Modulation (FQAM) andsliding window superposition coding (SWSC) as an advanced codingmodulation (ACM), and filter bank multi carrier (FBMC), non-orthogonalmultiple access(NOMA), and sparse code multiple access (SCMA) as anadvanced access technology have been developed.

The Internet, which is a human centered connectivity network wherehumans generate and consume information, is now evolving to the Internetof Things (IoT) where distributed entities, such as things, exchange andprocess information without human intervention. The Internet ofEverything (IoE), which is a combination of the IoT technology and theBig Data processing technology through connection with a cloud server,has emerged. As technology elements, such as “sensing technology”,“wired/wireless communication and network infrastructure”, “serviceinterface technology”, and “Security technology” have been demanded forIoT implementation, a sensor network, a Machine-to-Machine (M2M)communication, Machine Type Communication (MTC), and so forth have beenrecently researched. Such an IoT environment may provide intelligentInternet technology services that create a new value to human life bycollecting and analyzing data generated among connected things. IoT maybe applied to a variety of fields including smart home, smart building,smart city, smart car or connected cars, smart grid, health care, smartappliances and advanced medical services through convergence andcombination between existing Information Technology (IT) and variousindustrial applications.

In line with this, various attempts have been made to apply 5Gcommunication systems to IoT networks. For example, technologies such asa sensor network, Machine Type Communication (MTC), andMachine-to-Machine (M2M) communication may be implemented bybeamforming, MIMO, and array antennas. Application of a cloud RadioAccess Network (RAN) as the above-described Big Data processingtechnology may also be considered to be as an example of convergencebetween the 5G technology and the IoT technology.

Recently, with the development of Long Term Evolution (LTE) andLTE-Advanced, researches for technology to operate a mobilecommunication system in an unlicensed band have been actively made, andin particular, channel sensing (or listen-before-talk) may be needed insuch an unlicensed band. In this case, there is a need for a method andan apparatus for smoothly operating the mobile communication system inthe unlicensed band.

SUMMARY

To address the above-discussed deficiencies, it is a primary object isto provide a method and an apparatus for transmitting uplink controlinformation more efficiently through configuration of a cell in whichthe uplink control information of a terminal is transmitted inaccordance with at least one of whether to transmit an uplink datachannel and whether the uplink control information can be transmitted ina mobile communication system that operates in an unlicensed band or ina mobile communication system that requires channel sensing (orlisten-before-talk).

In accordance with an aspect of the present disclosure, a method forreceiving uplink control information of a base station includestransmitting configuration information of one or more serving cells thatoperate in an unlicensed band to a terminal; transmitting informationindicating that an uplink control channel and an uplink data channel canbe simultaneously transmitted to the terminal; determining whether theterminal is configured to transmit at least one of data and the uplinkcontrol information through the uplink data channel in at least one of alicensed band and the unlicensed band; and receiving the uplink controlinformation in at least one of the licensed band and the unlicensed bandon the basis of the determination, wherein the configuration informationincludes unlicensed-band uplink control channel configurationinformation for configuring the uplink control channel in one of theserving cells that operate in the unlicensed band.

If only the unlicensed-band serving cell in which the uplink controlchannel is configured is in an idle state in the case where the terminalis configured not to transmit at least one of the data and the uplinkcontrol information through the uplink data channel in the licensed bandas the result of the determination, the uplink control information maybe received through the uplink control channel and the uplink datachannel in a state where the uplink data channel is configured in theunlicensed-band serving cell in which the uplink control channel isconfigured, whereas the uplink control information may be receivedthrough the uplink control channel in a state where the uplink datachannel is not configured in the unlicensed-band serving cell in whichthe uplink control channel is configured.

If the unlicensed-band serving cell in which the uplink control channelis configured is not in an idle state, but the at least oneunlicensed-band serving cell in which the uplink data channel isconfigured is in the idle state in the case where the terminal isconfigured not to transmit at least one of the data and the uplinkcontrol information through the uplink data channel in the licensed bandas the result of the determination, the uplink control information maybe received through the uplink data channel of the cell having thelowest cell index among the unlicensed-band serving cells in which theuplink data channel is configured.

In the case where the terminal is configured to transmit at least one ofthe data and the uplink control information through the uplink datachannel in the licensed band as the result of the determination, theuplink control information may be received through the uplink datachannel in the licensed band.

If the unlicensed-band serving cell in which the uplink control channelis configured is in an idle state in the case where the terminal isconfigured not to transmit at least one of the data and the uplinkcontrol information through the uplink data channel in the licensed bandand the unlicensed band as the result of the determination, the uplinkcontrol information may be received through the uplink control channel,whereas if the unlicensed-band serving cell is not in the idle state,the uplink control information may be received through the uplinkcontrol channel in the licensed band.

In accordance with another aspect of the present disclosure, a methodfor transmitting uplink control information of a terminal includesreceiving configuration information of one or more serving cells thatoperate in an unlicensed band from a base station; receiving informationindicating that an uplink control channel and an uplink data channel canbe simultaneously transmitted from the base station; determining whetherit is configured to transmit at least one of data and the uplink controlinformation through the uplink data channel in at least one of alicensed band and the unlicensed band; and transmitting the uplinkcontrol information in at least one of the licensed band and theunlicensed band on the basis of the determination, wherein theconfiguration information includes unlicensed-band uplink controlchannel configuration information for configuring the uplink controlchannel in one of the serving cells that operate in the unlicensed band.

In accordance with still another aspect of the present disclosure, abase station for receiving uplink control information includes atransceiver unit configured to transmit and receive signals with aterminal; and a control unit configured to control the transceiver unitto transmit configuration information of one or more serving cells thatoperate in an unlicensed band and information indicating that an uplinkcontrol channel and an uplink data channel can be simultaneouslytransmitted to the terminal, to determine whether the terminal isconfigured to transmit at least one of data and the uplink controlinformation through the uplink data channel in at least one of alicensed band and the unlicensed band, and to control the transceiverunit to receive the uplink control information in at least one of thelicensed band and the unlicensed band on the basis of the determination,wherein the configuration information includes unlicensed-band uplinkcontrol channel configuration information for configuring the uplinkcontrol channel in one of the serving cells that operate in theunlicensed band.

In accordance with yet still another aspect of the present disclosure, aterminal for transmitting uplink control information includes atransceiver unit configured to transmit and receive signals with a basestation; and a control unit configured to control the transceiver unitto receive configuration information of one or more serving cells thatoperate in an unlicensed band and information indicating that an uplinkcontrol channel and an uplink data channel can be simultaneouslytransmitted from the base station, to determine whether it is configuredto transmit at least one of data and the uplink control informationthrough the uplink data channel in at least one of a licensed band andthe unlicensed band, and to control the transceiver unit to transmit theuplink control information in at least one of the licensed band and theunlicensed band on the basis of the determination, wherein theconfiguration information includes unlicensed-band uplink controlchannel configuration information for configuring the uplink controlchannel in one of the serving cells that operate in the unlicensed band.

According to the aspects of the present disclosure, uplink controlinformation can be efficiently transmitted and complexity of a terminalcan be minimized through configuration of a cell in which the uplinkcontrol information of the terminal is transmitted in accordance with atleast one of whether to transmit an uplink data channel and whether theuplink control information can be transmitted.

Before undertaking the DETAILED DESCRIPTION below, it may beadvantageous to set forth definitions of certain words and phrases usedthroughout this patent document: the terms “include” and “comprise,” aswell as derivatives thereof, mean inclusion without limitation; the term“or,” is inclusive, meaning and/or; the phrases “associated with” and“associated therewith,” as well as derivatives thereof, may mean toinclude, be included within, interconnect with, contain, be containedwithin, connect to or with, couple to or with, be communicable with,cooperate with, interleave, juxtapose, be proximate to, be bound to orwith, have, have a property of, or the like; and the term “controller”means any device, system or part thereof that controls at least oneoperation, such a device may be implemented in hardware, firmware orsoftware, or some combination of at least two of the same. It should benoted that the functionality associated with any particular controllermay be centralized or distributed, whether locally or remotely.Definitions for certain words and phrases are provided throughout thispatent document, those of ordinary skill in the art should understandthat in many, if not most instances, such definitions apply to prior, aswell as future uses of such defined words and phrases.

BRIEF DESCRIPTION OF THE DRAWINGS

For a more complete understanding of the present disclosure and itsadvantages, reference is now made to the following description taken inconjunction with the accompanying drawings, in which like referencenumerals represent like parts:

FIGS. 1 and 2 are diagrams illustrating a communication system to whichthe present disclosure is applied;

FIG. 3 is a diagram illustrating a wireless resource configuration of anLTE system;

FIG. 4 is a diagram illustrating downlink channel connection in anunlicensed band of an LAA system;

FIG. 5 is a diagram illustrating uplink channel connection in anunlicensed band of an LAA system;

FIG. 6 is a flowchart illustrating a base station operation method forreceiving UCI information;

FIG. 7 is a flowchart illustrating a terminal operation method fortransmitting UCI information;

FIG. 8 is a diagram illustrating a base station device according toembodiments of the present disclosure; and

FIG. 9 is a diagram illustrating a terminal device according toembodiments of the present disclosure.

DETAILED DESCRIPTION

FIGS. 1 through 9, discussed below, and the various embodiments used todescribe the principles of the present disclosure in this patentdocument are by way of illustration only and should not be construed inany way to limit the scope of the disclosure. Those skilled in the artwill understand that the principles of the present disclosure may beimplemented in any suitably arranged electronic device.

Hereinafter, embodiments of the present disclosure will be described indetail with reference to the accompanying drawings. In describing thepresent disclosure, related well-known functions or configurationsincorporated herein are not described in detail in the case where it isdetermined that they obscure the subject matter of the presentdisclosure in unnecessary detail. Further, terms to be described laterare terms defined in consideration of their functions in the presentdisclosure, but may differ depending on intentions of a user and anoperator or customs. Accordingly, they should be defined on the basis ofthe contents of the whole description of the present disclosure.

The aspects and features of the present disclosure and methods forachieving the aspects and features will be apparent by referring to theembodiments to be described in detail with reference to the accompanyingdrawings. However, the present disclosure is not limited to theembodiments disclosed hereinafter, but can be implemented in diverseforms. The matters defined in the description, such as the detailedconstruction and elements, are nothing but specific details provided toassist those of ordinary skill in the art in a comprehensiveunderstanding of the disclosure, and the present disclosure is onlydefined within the scope of the appended claims. In the entiredescription of the present disclosure, the same drawing referencenumerals are used for the same elements across various figures.

Recently, a mobile communication system has been developed from aninitial mobile communication system that provides voice-orientedservices to a high-speed and high-quality wireless packet datacommunication system that provides data and multimedia services. Inorder to support such high-speed and high-quality wireless packet datatransmission services, various mobile communication standards, such as3rd Generation Partnership Project (3GPP) High Speed Downlink PacketAccess (HSDPA), High Speed Uplink Packet Access (HSUPA), Long TermEvolution (LTE), and Long Term Evolution Advanced (LTE-A), 3GPP2 HighRate Packet Data (HRPD), and Institute of Electrical and ElectronicsEngineers (IEEE) 802.16, have been developed.

In particular, standards development and evolution ofLTE/LTE-A/LTE-A-Pro (hereinafter referred to as “LTE”) have beencontinuously repeated to improve system capacity and frequencyefficiency. Representatively, an LTE system can greatly increase thedata rate and the system capacity in accordance with the usablefrequency bandwidth using Carrier Aggregation (CA) that can operate thesystem using plural frequency bands. However, the frequency band inwhich the LTE system currently operates corresponds to a licensed band(or licensed spectrum or licensed carrier) that can be exclusively usedby a specific operator that has its own authority. However, in the caseof general frequency bands (e.g., frequency bands that are equal to orlower than 5 GHz) for providing mobile communication services, otheroperators or other communication systems have already used them, andthus it is difficult for mobile communication service providers tosecure plural licensed frequency bands.

Accordingly, in order to efficiently process mobile data that areexplosively being increased in an environment in which it is difficultto secure such licensed frequency bands, technology to make efficientuse of an LTE system in an unlicensed band (or unlicensed spectrum orunlicensed carrier) (e.g., LTE in Unlicensed (LTE-U) orLicensed-Assisted Access (LAA)) has recently been studied. In anunlicensed band, a specific operator or a specific system does notexclusively use a specific band, but all allowable communication devicesshare and use the same frequency band. In this case, since 5 GHzunlicensed band is used by a relatively small number of communicationdevices in comparison to 2.4 GHz unlicensed band, and enables very widebandwidth to be utilized, it may be one of unlicensed frequency bandsthat facilitate security of additional frequency bands.

In the case of making efficient use of a licensed band and an unlicensedband using LTE technology that aggregates and use plural frequencybands, in other words, Carrier Aggregation (CA) technology, the systemcapacity can be easily increased. That is, the LTE system can beoperated in a licensed band and an unlicensed band through configurationof an LTE cell in the licensed band as a PCell (or Pcell) andconfiguration of an LTE cell (or LAA cell or LTE-U cell) in theunlicensed band as an SCell (or Scell or LAA SCell) using the CAtechnology. In this case, the above-described system can be applied tonot only the CA environment in which the licensed band and theunlicensed band are connected through ideal backhaul but also thedual-connectivity environment in which the licensed band and theunlicensed band are connected through non-ideal backhaul. In the presentdisclosure, explanation will be made on the assumption that the systemis applied to the CA environment in which the licensed band and theunlicensed band are connected through the ideal backhaul.

FIGS. 1 and 2 are diagrams illustrating a communication system to whichthe present disclosure is applied.

Referring to FIG. 1 that illustrates a case where an LTE cell 110 and anLAA cell 120 coexist in one small base station 100, a terminal 130transmits and receives data with the base station 100 through the LTEcell 110 and the LAA cell 120. There is no limit in a duplex type of theLTE cell 110 or the LAA cell 120, but it may be assumed that a cell thatperforms data transmission/reception using a licensed band is an LTEcell 110 or a PCell, and a cell that performs datatransmission/reception using an unlicensed band is an LAA cell 120 or anSCell. However, in the case where the LTE cell is the PCell, it may belimited that uplink transmission can be performed only through the LTEcell 110.

FIG. 2 illustrates installation of an LTE macro base station 200 forwide coverage and an LAA small base station 210 for data rate increasein a network. In this case, there is no limit in a duplex type of theLTE macro base station 200 or the LAA small base station 210. In thiscase, the LTE macro base station 200 may be replaced by the LTE smallbase station. Further, in the case where the LTE cell is the PCell, itmay be configured that uplink transmission can be performed only throughthe LTE base station 200. In this case, it is assumed that the LTE basestation 200 and the LAA base station 210 have an ideal backhaul network.Accordingly, X2 communication 220 becomes possible between fast basestations, and even if the uplink transmission is possible only betweenthe terminal and the LTE base station 200, the LAA base station 210 canreceive related control information in real time from the LTE basestation 200 through the X2 communication 220. Schemes that are proposedin the present disclosure can be applied to both the system of FIG. 1and the system of FIG. 2.

In general, an LTE/LTE-A system is a system that transmits data using anOrthogonal Frequency Division Multiple Access (OFDM) transmissionsystem. In the OFDM system, a modulation signal is located in 2Dresources that are composed of time and frequency. Resources on the timeaxis are discriminated from each other through different OFDM symbols,and are orthogonal to each other. Resources on the frequency axis arediscriminated from each other through different subcarriers, and arealso orthogonal to each other.

That is, in the OFDM system, one minimum unit resource may be indicatedthrough designation of a specific OFDM symbol on the time axis anddesignation of a specific subcarrier on the frequency axis, and may becalled a Resource Element (RE). Different REs have the characteristicsof being orthogonal to each other even if they pass through frequencyselective channels, and thus signals that are transmitted on thedifferent REs can be received in the reception side without generatingmutual interference.

FIG. 3 is a diagram illustrating downlink physical resources of an LTEsystem.

In an OFDM communication system, a downlink bandwidth is composed of aplurality of Resource Blocks (hereinafter referred to as “RBs”), andeach Physical Resource Block (hereinafter referred to as “PRB”) may becomposed of 12 subcarriers that are arranged along the frequency axisand 7 or 6 OFDM symbols that are arranged along the time axis as shownin FIG. 3. On the time axis, a subframe is composed of two slots, thatis, a first slot and a second slot, each of which has a length of 0.5 msas shown in FIG. 3. From the wireless resources as illustrated in FIG.3, different kinds of signals may be transmitted as follows.

-   -   Cell Specific RS (CRS) 300: This is a reference signal which is        periodically transmitted for all terminals that belong to one        cell. The CRS may be commonly used by a plurality of terminals.    -   Demodulation Reference Signal (DMRS) 310: This is a reference        signal that is transmitted for a specific terminal. The DMRS is        transmitted only in the case where data is transmitted to the        corresponding terminal. The DMRS may be composed of 8 DMRS ports        in all. In the LTE/LTE-A, ports 7 to 14 correspond to DMRS        ports, and the respective ports maintain orthogonality so that        they do not generate interference with each other using CDM or        FDM.    -   Physical Downlink Shared Channel (PDSCH) 340: This is a data        channel for downlink data. The PDSCH is used for the base        station to transmit traffic to the terminal, and is transmitted        using an RE on which the reference signal is not transmitted in        a data region that is a region excluding a control channel        region of FIG. 3.    -   Channel Status Information Reference Signal (CSI-RS) 320: This        is a reference signal that is transmitted for terminals that        belong to one cell. The CSI-RS is used to measure the channel        state. A plurality of CSI-RSs may be transmitted to one cell. In        the LTE-A system, one CSI-RS may correspond to one, two, four,        or eight antenna ports.    -   Other control channels (including PHICH, PCFICH, and PDCCH) 330:        This is used to provide control information that is required for        the terminal to receive the PDSCH or to transmit ACK/NACK for        operating HARQ for uplink data transmission.

A Physical Dedicated Control Channel (PDCCH) region that is a controlchannel region and an enhanced PDCCH (ePDCCH) region that uses a datachannel region are divided from each other on the time axis. This is toquickly receive and demodulate the control channel signal. In addition,the PDCCH region is located over the whole downlink band in a mannerthat one control channel is divided into control channels of a smallunit, and the small-unit control channels are dispersedly located on thewhole downlink band. An uplink is briefly divided into a control channelPUCCH and a data channel PUSCH. If the data channel does not exist, aresponse to the downlink data channel and other feedback information aretransmitted through the control channel, whereas if the data channelexists, they are transmitted through the data channel. Hereinafter, thePDCCH transmission may mean transmission of the control signal on thePDCCH, and the PDSCH transmission or the PUSCH transmission may meantransmission of the signal on the PDSCH or the PUSCH.

In this case, at least one of the control signals, control channels, anddata channels may be transmitted and received using parts of SC-FDMA orOFDM symbols in uplink or downlink subframes that are used to performLTE communications. For example, transmission/reception of the controlsignals or channels or data channels may be performed using thesubframes or k to 13 OFDM symbols (where, k1>0), which performtransmission of the control signals or channels or data channels using 0to k1 OFDM symbols (where, k1<13) among 14 OFDM symbols (0 to 13 OFDMsymbol indexes) that constitute 1 ms subframe. In this case, thesubframes that transmit and receive the control signals or channels ordata channels using partial symbols in the subframe as described abovemay be expressed as partial subframes.

Hereinafter, preferred embodiments of the present disclosure will bedescribed in detail with reference to the accompanying drawings. Indescribing the present disclosure, related well-known functions orconfigurations incorporated herein are not described in detail in thecase where it is determined that they obscure the subject matter of thepresent disclosure in unnecessary detail. Further, terms to be describedlater are terms defined in consideration of their functions in thepresent disclosure, but may differ depending on intentions of a user andan operator or customs. Accordingly, they should be defined on the basisof the contents of the whole description of the present disclosure.Further, although a system that transmits and receives signals using atleast one unlicensed band in a Long Term Evolution (LTE) system, anLTE-Advanced (LTE-A) system, and an LTE-A-Pro system is exemplarilydescribed in the description of the present disclosure, the presentdisclosure can be applied to other communication systems thatsimultaneously use a licensed band and an unlicensed band or acommunication system that senses a frequency band for performing thesignal transmission (or measures the strength of a received signal)before the signal transmission, and performs or does not perform thesignal transmission in accordance with the result of the sensing withoutany particular addition and subtraction. Further, in the presentdisclosure, a base station or a cell that performs communication usingan unlicensed band may be expressed as an LAA SCell, an LAA Cell, an LAAbase station, a base station, or a cell, and a terminal that performscommunication using an unlicensed band may be mixedly expressed as anLAA terminal, an LAA UE, or a terminal. However, in the embodiments ofthe present disclosure, the above-described expressions have the samemeaning.

Further, for convenience in explanation, it is assumed that the presentdisclosure is applied to a Carrier Aggregation (CA) environment in whichat least one licensed band cell and one or more unlicensed band cellsare connected through an ideal backhaul. However, the present disclosureis not limited thereto, but may be applied even to a dual-connectivityenvironment in which the cells are connected through a non-idealbackhaul or a stand-alone environment in which only cells that operateonly in an unlicensed band are connected to each other without anylicensed band cell. Further, in the present disclosure, explanation willbe made on the assumption that an LAA terminal transmits an uplinkcontrol signal or channel or uplink data to an LAA cell using anunlicensed band. However, the present disclosure can also be applied toa case where an LAA cell transmits a downlink control signal or channelor downlink data to an LAA terminal using an unlicensed band.

Generally, in the unlicensed band, a plurality of devices share and usethe same frequency band or channel. In this case, the devices that usethe unlicensed band may use different systems. Accordingly, for mutualcoexistence between various devices, the devices that operate in theunlicensed band may perform channel sensing with respect to theunlicensed band before performing communication using the unlicensedband or channel, and may perform or may not perform communication withrespect to the unlicensed band in accordance with the result of thechannel sensing. In this case, if the unlicensed band can be used inaccordance with the result of the channel sensing, the device cancontinuously occupy and use the unlicensed band for a Maximum ChannelOccupancy Time (MCOT) that is predefined or preconfigured.

General operations of the devices that operate in the unlicensed bandare as follows. A transmission device that requires signal transmissionincluding data or a control signal may confirm whether other devicesoccupy (or use) the unlicensed band or channel in which the signaltransmission is performed before performing the signal transmission, andmay occupy or may not occupy the channel in accordance with theconfirmed channel occupation state of other devices. Such an operationis generally called Listen-Before-Talk (LBT) (or channel sensing). Inother words, at least the transmission device among the devices thatintend to perform communication using the unlicensed band shoulddetermine whether to occupy the channel in accordance with thepredefined or preconfigured method.

In this case, in order to determine whether to occupy the unlicensedband or channel, time that is required to sense the channel may bepredefined, may be configured from the transmission device or a specificdevice, or may be selected as an arbitrary value in a specific range.Further, the channel sensing time may be configured in proportion to themaximum channel occupation time in which the unlicensed band can becontinuously occupied at maximum without any separate channel sensingoperation. Further, the channel sensing time for performing the channelsensing operation may be configured in accordance with the maximumchannel occupation time. In this case, at least one configuration valueof the channel sensing operation may be differently configured inaccordance with the unlicensed band for performing the operation or inaccordance with regional or national regulations. For example, in thecase of the United States, the unlicensed band can be currently usedwithout separate channel sensing operation except for a radar sensingoperation in 5 GHz frequency band.

The transmission device that intends to use the unlicensed band maysense whether other devices use the corresponding channel through theabove-described channel sensing operation (or LBT), and if it is sensedthat other devices do not occupy the corresponding channel, thetransmission device may occupy and use the channel. At this time, thedevices that use the unlicensed band may operate to predefine orconfigure the maximum channel occupation time for the continuousoccupation after the channel sensing operation. In this case, themaximum occupation time may be predefined in accordance with regulationsthat are defined according to the frequency band, regional and/ornational regulations, or may be separately configured from anotherdevice (e.g., in the case of the terminal, the base station). Forexample, in the case of Japan, the maximum occupation time in 5 GHzunlicensed band is restricted to 4 ms.

A channel occupation method in an LAA cell in order for an LAA system touse an unlicensed band is as follows. If the intensity of a signal thatis received during the whole or a part of a fixed channel sensing periodis higher than a predefined threshold value in the case where a channelsensing operation is performed with respect to the correspondingunlicensed band for the fixed period (e.g., 25 □s) in the LAA cell, theLAA cell determines that at least one of other devices uses theunlicensed band, and does not perform communication using the unlicensedband. If the intensity of the signal that is received during the wholeof the fixed channel sensing period is lower than the predefinedthreshold value, the LAA cell determines that the unlicensed band is inan idle state, and thus can continuously use the unlicensed band for themaximum channel occupation period that is predefined or preconfigured.

If the intensity of the signal that is received during a part of avariable channel sensing period is higher than the predefined thresholdvalue in the case where the channel sensing operation is performed withrespect to the corresponding unlicensed band for the configured variableperiod in the LAA cell, the LAA cell determines that at least one ofother devices uses the unlicensed band, and does not performcommunication using the unlicensed band. If the intensity of the signalthat is received during the whole of the variable channel sensing periodis lower than the predefined threshold value, the LAA cell determinesthat the unlicensed band is in an idle state, and thus can continuouslyuse the unlicensed band for the maximum channel occupation period thatis predefined or preconfigured.

In this case, the variable channel sensing period may be varied throughselection of an arbitrary value in a contention window that isconfigured or managed by the LAA cell. For example, the LAA cell mayselect an arbitrary variable N (e.g., in the case where a maximum valueof an initial contention window is 15, the LAA cell may select anarbitrary integer N) from a channel contention window set that isselected on the basis of at least one of the kind of the signal to betransmitted by the LAA cell and the maximum channel occupation period tobe maximally occupied by the LAA cell, may perform the channel sensingoperation as long as the selected N period, and then may occupy and usethe unlicensed band. In this case, the probability that other devicescan simultaneously use the unlicensed band can be lowered by changing orinitializing the contention window on the basis of the result ofreception of the terminal (e.g., ACK/NACK that is transmitted by theterminal) with respect to the data signal that is transmitted throughthe unlicensed band. For example, if NACK generation exceeds 80% of thereception results of all terminals with respect to data signals that aretransmitted from the very first subframe in the maximum channeloccupation period through the unlicensed band, the LAA cell increasesthe contention window. If the NACK generation does not exceed 80% of thereception results of all terminals with respect to the data signals thatare transmitted from the very first subframe in the maximum channeloccupation period through the unlicensed band, the LAA cell configuresthe contention window as an initial value.

FIG. 4 is a diagram illustrating an LAA downlink transmission operation.

A general LAA downlink transmission operation will now be described withreference to FIG. 4. An LAA cell that transmits a downlink signal usingan unlicensed band performs channel sensing operation with respect tothe unlicensed band for a time 400 that corresponds to a variable periodthat is arbitrarily selected in a configured contention window. If it isdetermined that the unlicensed band is in an idle state through thechannel sensing operation, the LAA cell can occupy the unlicensed bandfor the maximum channel occupation period 450. In this case, if thechannel sensing operation is ended before a subframe boundary or a slotboundary, the LAA cell may occupy the unlicensed band throughtransmission of a predefined signal 420 up to the subframe or slotboundary, and may transmit general LTE signals (e.g., a control signal430 on PDCCH, a data signal 440 on PDSCH, and a reference signal) in aslot or subframe. In this case, the last subframe in the maximum channeloccupation period may be a partial subframe 470 in accordance with anoccupation start time of the unlicensed band and the maximum channeloccupation period.

FIG. 5 is a diagram illustrating an LAA uplink transmission operation.

A general LAA uplink transmission operation will now be described withreference to FIG. 5. An LAA terminal that transmits an uplink signalusing an unlicensed band may receive uplink transmission configurationthrough control information that is transmitted onto a downlink controlchannel 510 in subframe n in a downlink transmission period 500 of anLAA cell, and may perform uplink transmission 530 in subframe n+4 inwhich the uplink transmission has been configured through the uplinktransmission configuration. In this case, if the uplink transmission ofthe LAA terminal is uplink transmission in the unlicensed band, the LAAterminal should perform channel sensing operation before performing theconfigured uplink transmission 530. In this case, the channel sensingoperation that is performed by the LAA terminal may be equal to thechannel sensing operation that is performed by the LAA cell, or partialvariables (e.g., contention window sizes) may differ from each other.Further, the channel sensing operation 525 of the LAA terminal may beperformed in at least one SC-FDMA symbol 540 in the same subframe inwhich the uplink transmission has been configured, or may be performedin at least one SC-FDMA symbol 525 just before the configured uplinksubframe. In this case, the LAA terminal may perform or may not performthe configured uplink transmission in accordance with the result of thechannel sensing operation.

In an LTE system, a terminal may perform uplink data transmission inaccordance with base station configuration or instructions. For example,uplink signal transmission on an uplink data channel (hereinafterreferred to as “Physical Uplink Shared Channel (PUSCH)”) of the terminalis performed as follows. If a base station instructs a specific terminalto perform uplink transmission through control information on a downlinkcontrol channel (hereinafter referred to as “Physical Downlink ControlChannel (PDCCH)”), the terminal transmits the configured uplink signalusing the time relationship between an uplink transmission configurationreception time (e.g., PDCCH reception time) that is predefined with thebase station and a configured uplink signal transmission time (e.g.,PUSCH transmission time). The base station may configure data or CSI(non-periodic CSI) so that the terminal transmits the configured data orCSI using the PUSCH.

For example, in the case of an FDD system, if the base station instructsthe terminal to perform PUSCH transmission through the PDCCH in subframen, the terminal performs the PUSCH transmission using resources that areconfigured from the base station in subframe n+K (K=4). In this case, Kmay be configured as a different value including 4. In the case of a TDDsystem, the terminal may perform PUSCH transmission using therelationship between a PDCCH reception time and a PUSCH transmissiontime, which includes uplink transmission configuration information thatis predefined between the base station and the terminal. At this time,in the case of a system having a third frame structure except for theFDD and TDD, the time relationship that is defined in the FDD or TDDsystem may be reused as the time relationship between the uplinktransmission configuration information reception time and the configureduplink signal transmission time, or a new time relationship between theuplink transmission configuration reception time and the configureduplink signal transmission time may be defined for the system having thethird frame structure.

Similarly in the LTE system, the terminal may transmit Uplink ControlInformation (UCI) to the base station using at least one of a PhysicalUplink Control Channel (PUCCH) and PUSCH that are determined by at leastone standard including the kind of the UCI and base station/terminalconfiguration in accordance with the base station configuration orinstructions. Here, the UCI information may be composed of one or moreof HARQ-ACK, periodic CSI, non-periodic CSI, and scheduling requestinformation. For example, the terminal may periodically report ChannelState Information (CSI) to the base station through the PUCCH inaccordance with a period that the base station has configured as anupper signal. If the base station instructs the terminal tonon-periodically report the CSI through the PDCCH, the terminal mayreport the measured CSI to the base station through the PUSCH that isconfigured by the PDCCH.

The base station and the terminal that are described in the presentdisclosure relate to a base station and a terminal that cantransmit/receive signals from one or more cells that operate in alicensed band or an unlicensed band, and may also include a base stationand a terminal that can transmit/receive signals from one or more cellsthrough the licensed band, and a base station that can transmit signalsto one or more cells through the unlicensed band and a terminal that canreceive a signal from one or more cells through the unlicensed band.Unless separately explained, it is assumed that the terminal and thebase station that are described in the present disclosure are configuredto transmit/receive signals from one or more cells. In this case,explanation will be made on the assumption that the configured cells arecomposed of cells that operate in at least one licensed band and cellsthat operate in at least one unlicensed band. In this case, the presentdisclosure can be applied even to a base station and a terminal thatoperate only in the unlicensed band without separate licensed band.

Further, it is assumed that the cell that operates in the licensed band,or the base station and the terminal, which are described in the presentdisclosure, are configured and operate in at least one duplex type ofFDD (or frame structure type 1) and TDD (or frame structure type 2).Similarly, it is assumed that the cell that operates in the licensedband, or the base station and the terminal, which are described in thepresent disclosure, are configured and operate in the third framestructure (or frame structure type 3). Here, the frame structure type 3includes a frame structure that the channel sensing operation requires,and is structured so that all subframes can be configured as a downlinkor an uplink. Accordingly, the downlink and uplink periods can be freelychanged within a range that is permitted by the technology orregulations in accordance with the base station configuration.

Further, the method that is proposed in the present disclosure is notlimited to respective embodiments, but can be applied to all embodimentsdescribed in the present disclosure.

Hereinafter, a method for a terminal that can transmit/receive signalswith one or more cells that operate in a licensed band to transmit UCIwill be described.

UCI transmission cells may be changed in accordance with at least onecondition of the kind of UCI information (or UCI) (e.g., HARQ-ACK,Periodic CSI information (P-CSI), non-periodic CSI information (A-CSI),Scheduling Request (SR) information), which is transmitted in subframe nby the terminal in which simultaneous transmission of PUCCH and PUSCHhas been configured or has not been configured, whether to transmitPUSCH at UCI transmission time (or in subframe n), the kind of PUSCHtransmission cells, and cell indexes of PUSCH transmission cells.

Next, a UCI transmission method of a terminal in which simultaneoustransmission of PUCCH and PUSCH has not been configured will bedescribed.

For example, if there is not the configured PUSCH transmission at theUCI transmission time, the UCI (composed of at least one of HARQ-ACK,periodic CSI information, SR, and RI) is transmitted through PUCCH ofPCell. In this case, since it is assumed that the non-periodic CSI istransmitted through the PUSCH, it may be excluded from the PUCCHtransmission.

If the UCI information that is transmitted in subframe n includesnon-periodic CSI or non-periodic CSI and HARQ-ACK information, the UCIinformation is transmitted from the base station through the PUSCH thatis configured through the PDCCH. In this case, the base stationconfigures CSI information report request and PUSCH resources for theterminal to transfer the CSI information report to the terminal throughthe PDCCH. If PUSCH transmission for data transmission has beenconfigured at UCI information transmission time in the terminal, the UCIinformation may be included (embedded or multiplexed) in the PUSCHtransmission for the data transmission to be transmitted. In this case,the PUSCH for the CSI information request and the PUSCH for the datatransmission may be configured through one PDCCH, or may be respectivelyconfigured through separate PDCCHs.

If the UCI information that is transmitted in subframe n includes one ofperiodic CSI, HARQ-ACK, and periodic CSI and HARQ-ACK information, andthe PUSCH transmission in PCell is configured at the UCI transmissiontime, the UCI information to be transmitted may be included in the PUSCHtransmission of PCell. In this case, if the PUSCH transmission in thePCell is information that is transmitted during an initial cellconnection process, the UCI information may not be transmitted.

If the UCI information that is transmitted in subframe n includes one ofperiodic CSI, HARQ-ACK, and periodic CSI and HARQ-ACK information, andthe PUSCH transmission in PCell is not configured at the UCItransmission time, but the PUSCH is configured in at least one SCell,the UCI information to be transmitted may be included in the PUSCHtransmission of the SCell having the smallest SCellIndex among SCells inwhich the PUSCH transmission has been configured.

Hereinafter, a UCI transmission method of a terminal in whichsimultaneous transmission of PUCCH and PUSCH has been configured will bedescribed.

If the UCI information that is transmitted in subframe n includes atleast one of HARQ-ACK and/or SR, the UCI information may be transmittedusing at least one of PUCCH formats 1/1a/1b/3 in accordance with the UCIinformation and the base station configuration. Here, detailedinformation on the respective PUCCH formats that are described in thepresent disclosure refers to the latest 3GPP TS36.211, TS36.212, andTS36.213 standards.

If the UCI information that is transmitted in subframe n includes atleast one of HARQ-ACK and/or SR and/or periodic CSI information, the UCIinformation may be transmitted using at least one of PUCCH formats 4/5in accordance with the UCI information and the base stationconfiguration.

If the UCI information that is transmitted in subframe n includesperiodic CSI information for one serving cell, the UCI information maybe transmitted through PUCCH format 2.

If the UCI information that is transmitted in subframe n is composed ofperiodic CSI information and HARQ-ACK and PUSCH transmission in anothercell is not configured, the UCI information may be transmitted using atleast one of PUCCH formats 2a/2b/3/4/5 in accordance with the UCIinformation.

If the UCI information that is transmitted in subframe n is composed ofperiodic CSI information and HARQ-ACK and PUSCH transmission in PCell isconfigured in subframe n, the HARQ-ACK of the UCI information may betransmitted using at least one of PUCCH formats 1a/1b/3 in accordancewith the UCI information, and the periodic CSI information may betransmitted through the PUSCH of the PCell.

If the UCI information that is transmitted in subframe n is composed ofperiodic CSI information and HARQ-ACK, and the PUSCH transmission inPCell is not configured in subframe n, but the PUSCH transmission isconfigured in at least one SCell, the HARQ-ACK of the UCI informationmay be transmitted using at least one of PUCCH formats 1a/1b/3 inaccordance with the UCI information, and the periodic CSI informationmay be transmitted through the PUSCH of the SCell having the smallestSCellIndex among SCells in which the PUSCH transmission has beenconfigured in subframe n.

If the UCI information that is transmitted in subframe n is composed ofnon-periodic CSI information and HARQ-ACK, or non-periodic CSIinformation and HARQ-ACK and SR, or non-periodic CSI information and SR,the HAEQ-ACK of the UCI information, or the HARQ-ACK and the SR, or theSR may be transmitted using at least one of PUCCH formats 1/1a/1b/3 inaccordance with the UCI information, and the non-periodic CSIinformation may be transmitted through the transmission-configuredPUSCH.

In the present disclosure, the terminal is configured to transmit thePUCCH in one or more PUCCH groups or one or more cells, and the PUCCHtransmission cell may be not only a cell that operates in the licensedband but also a cell (PCell, PSCell, or SCell) that operates in theunlicensed band.

Further, in the present disclosure, it is assumed that cells thatoperate in the unlicensed band operate using different channels (thatmay be understood as frequency bands) in the unlicensed band. However,the present disclosure may also be applicable to a case where differentcells operate using the same unlicensed band channel. Further, inrelation to the UCI transmission that is described in the presentdisclosure, it is basically assumed that in the case where asimultaneousAckNackAndCQI field is configured as TRUE in the terminal,or simultaneous transmission of HARQ-ACK and CSI (CQI/PMI) isconfigured, the terminal simultaneously transmits HARQ-ACK and CQI/PMI.Further, in the case where transmission of HARQ-ACK and CSI (CQI/PMI)information should be simultaneously performed in the terminal in whichthe simultaneousAckNackAndCQI field is not configured as TRUE, it isbasically assumed that the terminal does not transmit the CSI, buttransmits the HARQ-ACK information.

In the terminal that is configured to transmit the PUCCH in one or morecells (e.g., terminal in which PUCCH transmission in PCell and PUCCHtransmission in PSCell or SCell have been configured), PUCCHtransmission group may be discriminated on the basis of a PUCCHtransmission cell. In this case, one cell in the PUCCH transmissiongroup may be configured as a PUCCH transmission cell. For example, if itis assumed that four cells, such as PCell, SCell1, SCell2, and SCell3,are configured in the terminal, and maximally two of the configuredPUCCH transmission cells are configured in the terminal, the PCell towhich the PUCCH is basically transmitted is configured as the PUCCHtransmission cell. One or more cells that include the PCell may beconfigured in one PUCCH group (or primary PUCCH group), and one or morecells that include the SCell in which the PUCCH transmission has beenconfigured among the cells that are not included in the primary PUCCHgroup may be configured as another PUCCH group (secondary PUCCH group).

For example, in the case where two PUCCH transmission cells areconfigured and PCell and SCell2 are configured as the PUCCH transmissioncells, PCell and SCell1 may be configured in one group (primary PUCCHgroup), and SCell2 and SCell3 may be configured in another PUCCH group(secondary PUCCH group). In this case, the PUCCH is always transmittedin the PCell among the cells of the PUCCH group in which the PCell isincluded. In the PUCCH group in which the PCell is not included, aspecific cell, for example, SCell2, may be configured as the PUCCHtransmission cell (PUCCH-SCell) in accordance with the base stationconfiguration. In this case, UCI information on PCell and SCell1 may betransmitted through the PUCCH, and UCI information on SCell2 and SCell3may be transmitted through the PUCCH of the SCell2 that is configured asthe PUCCH-SCell.

In the present disclosure, for convenience in explanation, two differentPUCCH cell groups (or two PUCCH transmission cell configurations) areassumed. However, even in the case of configuring two or more PUCCH cellgroups, various methods that are described in the present disclosure maybe applied. In the present disclosure, one of two different PUCCH cellgroups that includes PCell is expressed as a first PUCCH cell group, andthe other of two different PUCCH cell groups that does not include thePCell is expressed as a second PUCCH cell group. In this case, each ofthe PUCCH groups may be composed of at least one SCell, and PUCCHtransmission of the cells that belong to one PUCCH group is performed inthe cell that is configured as the PUCCH transmission cell in the PUCCHgroup.

Further, in the case where there is no separate description in thepresent disclosure, it is assumed that PCell is a cell that operates inthe licensed band, and the PUCCH transmission in the PCell is expressedas PUCCH or PUCCH-PCell. However, even in the case of the PCell thatoperates in the unlicensed band, the method that is described in thepresent disclosure can be applied. Further, the PUCCH-SCell that isexpressed in the present disclosure may be dividedly explained as SCell(PUCCH-SCell) that is a cell in which the PUCCH transmission has beenconfigured and operates in the licensed band and SCell (PUCCH-LAA-SCell)that operates in the unlicensed band. However, even in the case ofmixedly using them, they can be dividedly analyzed in accordance withthe point of argument that is described in the present disclosure. Inthe case where there is no separate description in the presentdisclosure, it is assumed that PCell of the first PUCCH group thatoperates in the licensed band and SCell of the second PUCCH group thatoperates in the unlicensed band are configured as the PUCCH transmissioncells of the respective groups in the terminal.

Further, the present disclosure relates to a base station and a terminalthat can transmit/receive signals using one or more cells that operatein a licensed band or an unlicensed band, and particularly relates to aterminal that is configured to add and activate the cells in order toperform uplink signal transmission from the base station to at least onelicensed band or unlicensed band cell. In particular, the presentdisclosure relates to a case where the terminal receives configurationof two or more PUCCH transmission cells from the base station, and atleast one of the configured PUCCH transmission cells is configured as acell that operates in the unlicensed band.

If at least one of the PUCCH transmission cells that are configured fromthe terminal to the base station is a cell that operates in theunlicensed band, the PUCCH in the PUCCH transmission cell (orPUCCH-LAA-SCell) can be transmitted or cannot be transmitted inaccordance with the channel sensing operation (or channel sensing)result in the unlicensed band in which the cell operates. In otherwords, the terminal, which intends to perform UCI transmission withrespect to at least one of cells in the second PUCCH group withoutseparate uplink data channel transmission in subframe n, determineswhether other devices occupy channels with respect to the unlicensedband based on various cases where the intensity of the signal that isreceived through the channel sensing operation is configured from thebase station or is higher than a predefined threshold value, and apredefined signal is detected. If it is determined that the unlicensedband is in an idle state as the result of performing the channel sensingoperation in the unlicensed band with respect to the PUCCH-LAA-SCell,the terminal may perform the PUCCH transmission of which thetransmission has been configured in the PUCCH-LAA-SCell. If it isdetermined that the unlicensed band is occupied by other devices inaccordance with the result of the channel sensing operation with respectto the PUCCH-LAA-SCell, the terminal may perform the PUCCH transmissionthat is configured with respect to the PUCCH-LAA-SCell.

In this case, if the terminal requires UCI transmission in subframe n,at least one of UCI information that is transmitted in subframe n,channel or transmission cell in which UCI is transmitted, and resourceallocation method for UCI information may be differently determined inaccordance with at least one condition of whether to configurePUCCH-PUSCH simultaneous transmission from the base station, the kind ofUCI information to be transmitted, and whether to configure PUSCHtransmission in subframe n. Further, at least one of PUCCH transmissioncells that are configured in the terminal in which one or more PUCCHtransmission cells have been configured is configured as a cell thatoperates in the unlicensed band, and if the UCI transmission is requiredin subframe n, at least one of UCI information that is transmitted insubframe n, channel or transmission cell in which UCI is transmitted,and resource allocation method for UCI information may be differentlydetermined in accordance with at least one condition of whether toconfigure PUCCH-PUSCH simultaneous transmission from the base station,the kind of UCI information to be transmitted, whether to configurePUSCH transmission in subframe n, the result of channel sensingoperation for the PUCCH transmission cells, and channel sensingoperation for the cell in which uplink transmission has been configuredamong unlicensed band cells that are included in a PUCCH group (thesecond PUCCH group) in which the PUCCH transmission cells are included.Accordingly, the present disclosure proposes a method for moreefficiently performing UCI transmission in the terminal.

Embodiment 1

Hereinafter, in the present disclosure, it is assumed that in a terminalin which one or more PUCCH transmission cells have been configured andPUCCH-PUSCH simultaneous transmission has not been configured, at leastone of the PUCCH transmission cells is configured as a cell thatoperates in an unlicensed band, and UCI (e.g., the whole or a part ofperiodic CSI information, non-periodic CSI information, HARQ-ACKinformation, and scheduling request information) transmission for aPUCCH group (or the second PUCCH group) that is composed of cells thatperform PUCCH transmission to the PUCCH transmission cell (hereinafterreferred to as “PUCCH transmission cell”) that operates in theconfigured unlicensed band is required in subframe n. A UCI transmissionmethod that is proposed in the present disclosure will be described asfollows. In this case, the method that is proposed in the presentdisclosure can be applied to all embodiments described in the presentdisclosure.

First, a case where PUSCH transmission for the unlicensed band PUCCHtransmission cell has been configured will be described. A case whereUCI to be transmitted is composed of one of periodic CSI information,HARQ-ACK, and periodic CSI information and HARQ-ACK will be described.Regardless of whether to configure PUSCH transmission for cells that areincluded in the group (the second PUCCH group) for the PUCCHtransmission cells, the terminal performs channel sensing operation forthe unlicensed band PUCCH transmission cell before a PUSCH transmissiontime that is configured in the PUCCH transmission cell in subframe n,and if it is determined that the unlicensed band is an idle channel, theterminal then transmits UCI that is included (or embedded ormultiplexed) in the PUSCH that is configured in the PUCCH cell. If it isdetermined that the unlicensed band is not an idle channel after thechannel sensing operation for the unlicensed band PUCCH transmissioncell, the terminal may not perform uplink transmission in subframe n, ormay transmit the UCI through the PUCCH of PCell. In this case, if thePUSCH transmission includes information on initial random access of theterminal, the UCI is not transmitted.

Next, a case where the UCI to be transmitted is composed of one ofperiodic CSI information, HARQ-ACK, and periodic CSI information andHARQ-ACK, and PUSCH transmission is configured for the cell thatoperates in at least one licensed band among the cells included in thegroup (the second PUCCH group) for the PUCCH transmission cells will bedescribed. Regardless of the result of the channel sensing operation forthe PUCCH transmission cells in subframe n, the terminal does notperform the channel sensing operation for the PUCCH transmission cell,but may transmit the UCI information that is included in the PUSCH inthe cell having the smallest SCellIndex among the cells in the licensedband in which the PUSCH transmission has been configured in subframe n.

Next, a case where UCI to be transmitted is composed of one of periodicCSI information, HARQ-ACK, and periodic CSI information and HARQ-ACK,and PUSCH transmission is configured for the cell that operates in atleast one unlicensed band among the cells included in the group (thesecond PUCCH group) for the PUCCH transmission cells will be described.The terminal performs channel sensing operation for the unlicensed bandPUCCH transmission cell before a PUSCH transmission time that isconfigured in the PUCCH transmission cell in subframe n, and if it isdetermined that the unlicensed band is an idle channel, the terminalthen transmits UCI that is included (or embedded or multiplexed) in thePUSCH that is configured in the PUCCH cell. Further, the terminalperforms the channel sensing operation for the unlicensed band PUSCHtransmission cell before the PUSCH transmission time that is configuredin the PUSCH transmission cells in subframe n, and if the PUCCHtransmission cell is included in the cells in which it is determinedthat the unlicensed band is an idle channel, the terminal then transmitsthe UCI that is included (or embedded or multiplexed) in the PUSCH thatis configured in the PUCCH cell. Further, the terminal performs thechannel sensing operation for the unlicensed band PUSCH transmissioncell before the PUSCH transmission time that is configured in the PUSCHtransmission cell in subframe n, and if it is determined that the PUCCHtransmission cell is not included in the cells in which it is determinedthat the unlicensed band is an idle channel, but the cell in which thePUSCH transmission has been configured is included therein, the terminalthen transmits the UCI that is included (or embedded or multiplexed) inthe PUSCH that is configured in the cell having the smallest SCellIndexamong the cells in which it is determined that the unlicensed band is anidle channel or in the cell in which it is first determined that theunlicensed band is an idle channel. If it is determined that theunlicensed band is not an idle channel after the channel sensingoperation for the unlicensed band PUCCH transmission cell, or if it isdetermined that the unlicensed band of the PUCCH transmission cell andthe PUSCH transmission cell is not an idle channel, the terminal may notperform the uplink transmission in subframe n or may transmit the UCIthrough the PUCCH of the PCell. In this case, if the PUSCH transmissionincludes information on initial random access of the terminal, the UCIis not transmitted.

Next, a case where PUSCH transmission for the unlicensed band PUCCHtransmission cell has not been configured will be described.

If the PUSCH transmission for the cell that is included in the group(the second PUCCH group) for the PUCCH transmission cell has not beenconfigured, the terminal performs channel sensing operation for theunlicensed band PUCCH transmission cell before the PUCCH transmissiontime in subframe n. Then, if it is determined that the unlicensed bandis an idle channel, the terminal transmits UCI through PUCCH that isconfigured in the PUCCH cell. In this case, the UCI is composed ofperiodic CSI and/or HARQ-ACK and/or SR. If it is determined that theunlicensed band is not an idle channel after the channel sensingoperation for the unlicensed band PUCCH transmission cell, the terminalmay not transmit the UCI through the PUCCH that is configured insubframe n or may transmit the UCI through the PUCCH of the PCell.

Next, a case where PUSCH transmission for the cell that operates in theunlicensed band among the cells that are included in the group (thesecond PUCCH group) for the PUCCH transmission cell has not beenconfigured, but PUSCH transmission for the cell that operates in atleast one licensed band has been configured will be described. The UCIinformation is composed of periodic CSI, HARQ-ACK, or periodic CSI andHARQ-ACK. The terminal may transmit the UCI information that is includedin the PUSCH that is configured in the cell having the smallestSCellIndex among the cells of the licensed band in which the PUSCHtransmission has been configured in subframe n. In this case, if the UCIinformation is composed of a non-periodic CSI information report, theterminal may transmit the UCI through the PUSCH in the licensed bandcell that is configured for the non-periodic CSI information report.

Next, a case where UCI to be transmitted is composed of one of periodicCSI information, HARQ-ACK, and periodic CSI information and HARQ-ACK,and PUSCH transmission is not configured for the cell that operates inthe licensed band among the cells that are included in the group (thesecond PUCCH group) for the PUCCH transmission cells, but PUSCHtransmission for the cell that operates in at least one unlicensed bandwill be described. The terminal performs channel sensing operation forthe unlicensed band PUCCH transmission cell before a PUCCH transmissiontime that is configured in the PUCCH transmission cell in subframe n,and if it is determined that the unlicensed band is an idle channel, theterminal then transmits UCI through PUCCH of a PUCCH cell. Further, theterminal performs the channel sensing operation for the unlicensed bandPUSCH transmission cell before the PUSCH transmission time that isconfigured in the respective cells in which the PUSCH transmission hasbeen configured, and if it is determined that at least one cell is anidle channel, the terminal then transmits the UCI that is included (orembedded or multiplexed) in the PUSCH that is configured in the cellhaving the smallest SCellIndex among the cells that are determined asthe idle channels or in the cell in which it is first determined thatthe unlicensed band is an idle channel (among the cells in which thePUSCH transmission has been configured). If it is determined that theunlicensed band is not an idle channel in all of the PUCCH transmissioncell and the PUSCH transmission cells, the terminal may not perform theuplink transmission in subframe n or may transmit the UCI through thePUCCH of the PCell.

Next, a case where PUSCH transmission for the cell that operates in atleast one licensed band and PUSCH transmission for the cell thatoperates in at least one unlicensed band among the cells that areincluded in the group (the second PUCCH group) for the PUCCHtransmission cell have been configured, and the UCI information iscomposed of periodic CSI, HARQ-ACK, or periodic CSI and HARQ-ACK will bedescribed. The terminal may transmit the UCI information that isincluded in the configured PUSCH in the cell having the smallestSCellIndex among the cells of the licensed band in which the PUSCHtransmission has been configured in subframe n. In this case, if the UCIinformation is composed of non-periodic CSI information and the cellthat is configured for the non-periodic CSI information report is thecell that operates in the licensed band, the terminal may transmit theUCI through the PUSCH in the configured licensed band cell. If the UCIinformation is composed of the non-periodic CSI information and the cellthat is configured for the non-periodic CSI information report is thecell that operates in the unlicensed band, the terminal performs thechannel sensing operation for the unlicensed band cell before the PUSCHtransmission of the configured unlicensed band cell, and if it isdetermined that the unlicensed band is an idle channel, the terminalperforms UCI transmission through the PUSCH of the cell that isconfigured for the non-periodic CSI information report in subframe n. Ifit is determined that the unlicensed band is not an idle channel, theterminal does not perform UCI transmission in subframe n.

Embodiment 2

Hereinafter, in the present disclosure, it is assumed that in a terminalin which one or more PUCCH transmission cells have been configured andPUCCH-PUSCH simultaneous transmission has been configured, at least oneof the configured PUCCH transmission cells is configured as a cell thatoperates in an unlicensed band, and UCI (e.g., UCI information of atleast one of periodic CSI, HARQ-ACK, scheduling request, periodic CSIand HARQ-ACK, HARQ-ACK and scheduling request, non-periodic CSI andHARQ-ACK, non-periodic CSI and scheduling request, or non-periodic CSIand HARQ-ACK and scheduling request) transmission for a PUCCH group (orthe second PUCCH group) that is composed of cells that perform PUCCHtransmission to the PUCCH transmission cell (hereinafter referred to as“PUCCH transmission cell”) that operates in the configured unlicensedband is required in subframe n. A UCI transmission method that isproposed in the present disclosure will be described as follows. In thiscase, the method that is proposed in the present disclosure can beapplied to all embodiments described in the present disclosure. In thiscase, if the periodic CSI and non-periodic CSI information reports occursimultaneously, the terminal may give preference to the non-periodic CSIinformation report without reporting the periodic CSI information, ormay give preference to the periodic CSI without reporting thenon-periodic CSI information.

Next, a case where PUSCH transmission in subframe n for the cell thatoperates in the licensed band among the cells that are included in thegroup (the second PUCCH group) for the configured unlicensed band PUCCHtransmission cell has not been configured, but PUSCH transmission forthe cell that operates in at least one unlicensed band has beenconfigured will be described. If it is determined that an unlicensedband channel of at least one of the cells is in an idle state after thechannel sensing operation for the PUCCH cell and/or PUSCH cell, a UCItransmission method of the terminal is determined in accordance with thecell in which it is determined that the unlicensed band channel is anidle channel, the kind of the UCI, and whether to transmit the PUSCH,and thus the present disclosure proposes a correct UCI transmissionmethod of the terminal in the above-described case.

For example, if the PUSCH transmission has not been configured in thecell that operates in the licensed band among the cells that areincluded in the group for a unlicensed band PUCCH transmission cell at aUCI information transmission time, the terminal may or may not transmitthe UCI information in accordance with the result of the channel sensingoperation in the reference cell on the basis of one of the PUCCH celland the unlicensed band cell in which the PUSCH transmission has beenconfigured. As another example, if the PUSCH transmission has beenconfigured in the cell that operates in at least one licensed band amongthe cells that are included in the group for the unlicensed band PUCCHtransmission cell at the UCI information transmission time, the terminaltransmits the UCI information that is included in the cell having thesmallest SCellIndex among the licensed band cells. Hereinafter, theabove-described case will be described in more detail.

A case where the PUSCH transmission in subframe n has not beenconfigured for the configured unlicensed band PUCCH transmission cellsthat are included in the group (the second PUCCH group) in the terminalthat performs UCI (e.g., periodic CSI, HARQ-ACK, scheduling request, orperiodic CSI and HARQ-ACK) transmission in subframe n will be described.If it is determined that the channel for the PUCCH cell is in an idlestate after the channel sensing operation for the PUCCH cell, theterminal may transmit the whole or a part of the UCI through the PUCCHthat is configured in the PUCCH cell. If it is determined that thechannel for the PUCCH cell among the cells is not in an idle state afterthe channel sensing operation for the PUCCH cell, the terminal may nottransmit the UCI information to the PUCCH cell, or may transfer the UCIinformation through the PUCCH of the PCell.

Next, a case where PUSCH transmission in subframe n for the cell thatoperates in the licensed band among the cells that are included in thegroup (the second PUCCH group) for the configured unlicensed band PUCCHtransmission cell has not been configured, but PUSCH transmission forthe cell that operates in at least one unlicensed band has beenconfigured in the terminal that performs UCI (e.g., periodic CSI,HARQ-ACK, scheduling request, or periodic CSI and HARQ-ACK) transmissionin subframe n will be described. If it is determined that only thechannel for the PUCCH cell among the above-described cells is in an idlestate after the channel sensing operation for the PUCCH cell and thePUSCH cell, and the PUSCH transmission in the PUCCH channel has not beenconfigured, the terminal may transmit the whole or a part of the UCIinformation through the PUCCH that is configured in the PUCCH cell.

Next, a case where PUSCH transmission in subframe n for the cell thatoperates in the licensed band among the cells that are included in thegroup (the second PUCCH group) for the configured unlicensed band PUCCHtransmission cell has not been configured, but PUSCH transmission forthe cell that operates in at least one unlicensed band has beenconfigured in the terminal that performs UCI (e.g., periodic CSI andHARQ-ACK) transmission in subframe n will be described. If it isdetermined that only the channel for the PUCCH cell among theabove-described cells is in an idle state after the channel sensingoperation for the PUCCH cell and the PUSCH cell, and the PUSCHtransmission in the PUCCH channel has been configured, the terminal maytransmit the periodic CSI that is included in the PUSCH that isconfigured in the PUCCH cell, and may transmit the UCI information thatexcludes the periodic CSI through the PUSCH that is configured in thePUCCH cell. If the transmission of the PUSCH that is configured in thePUCCH cell is signal transmission for an initial access of the terminal,the UCI is not transmitted.

Next, a case where PUSCH transmission in subframe n for the cell thatoperates in the licensed band among the cells that are included in thegroup (the second PUCCH group) for the configured unlicensed band PUCCHtransmission cell has not been configured, but PUSCH transmission forthe cell that operates in at least one unlicensed band has beenconfigured in the terminal that performs UCI (e.g., periodic CSI,HARQ-ACK, scheduling request, or periodic CSI and HARQ-ACK) transmissionin subframe n will be described. If it is determined that the channelfor the PUCCH cell among the above-described cells is not in an idlestate after the channel sensing operation for the PUCCH cell and thePUSCH cell, but the channel for at least one PUSCH transmission cell isin an idle state, the terminal may transmit at least the periodic CSI,HARQ-ACK, and periodic CSI and HARQ-ACK information of the UCIinformation that is included in the PUSCH that is configured in the cellhaving the smallest SCellIndex among the PUSCH cells in which it isdetermined that the channel is in the idle state, the cell in which itis most quickly determined that the channel is in the idle state, or thecell having the smallest SCellIndex among the cells in which it is mostquickly determined that the channel is in the idle state.

Next, a case where PUSCH transmission in subframe n for the cell thatoperates in the licensed band among the cells that are included in thegroup (the second PUCCH group) for the configured unlicensed band PUCCHtransmission cell has not been configured, but PUSCH transmission forthe cell that operates in at least one unlicensed band has beenconfigured in the terminal that performs UCI (e.g., periodic CSI,HARQ-ACK, scheduling request, or periodic CSI and HARQ-ACK) transmissionin subframe n will be described. If it is determined that the channelfor at least one PUSCH transmission cell including the PUCCH cell amongthe above-described cells is in an idle state after the channel sensingoperation for the PUCCH cell and the PUSCH cell, and the PUSCHtransmission in the PUCCH transmission cell has not been configured, theterminal may transmit at least the periodic CSI, HARQ-ACK, and periodicCSI and HARQ-ACK information of the UCI information that is included inthe PUSCH that is configured in the cell having the smallest SCellIndexamong the PUSCH cells in which it is determined that the channel is inthe idle state, the cell in which it is most quickly determined that thechannel is in the idle state, or the cell having the smallest SCellIndexamong the cells in which it is most quickly determined that the channelis in the idle state. Further, the terminal may transmit only theperiodic CSI information of the UCI information that is included in thePUSCH that is configured in the cell having the smallest SCellIndexamong the PUSCH cells in which it is determined that the channel is inthe idle state, the cell in which it is most quickly determined that thechannel is in the idle state, or the cell having the smallest SCellIndexamong the cells in which it is most quickly determined that the channelis in the idle state, and may transmit the whole or a part of the UCIinformation that excludes the periodic CSI information through the PUCCHthat is configured in the PUCCH cell.

Next, a case where PUSCH transmission in subframe n for the cell thatoperates in the licensed band among the cells that are included in thegroup (the second PUCCH group) for the configured unlicensed band PUCCHtransmission cell has not been configured, but PUSCH transmission forthe cell that operates in at least one unlicensed band has beenconfigured in the terminal that performs UCI (e.g., periodic CSI,HARQ-ACK, scheduling request, or periodic CSI and HARQ-ACK) transmissionin subframe n will be described. If it is determined that the channelfor at least one PUSCH transmission cell including the PUCCH cell amongthe above-described cells is in an idle state after the channel sensingoperation for the PUCCH cell and the PUSCH cell, and the PUSCHtransmission in the PUCCH transmission cell has been configured, theterminal may transmit the periodic CSI information of the UCIinformation that is included in the PUSCH that is configured in thePUCCH cell, and may transmit the whole or a part of the UCI informationthat excludes the periodic CSI information through the PUCCH that isconfigured in the PUCCH cell. In this case, it is also possible totransmit the UCI information that is entirely included in the PUSCH thatis configured in the PUCCH cell. If the transmission of the PUSCH thatis configured in the PUCCH cell is signal transmission for an initialaccess of the terminal, the UCI is not transmitted.

Next, a case where PUSCH transmission for non-periodic CSI transmissionin subframe n for the cells that are included in the group (the secondPUCCH group) for a configured unlicensed band PUCCH transmission cellhas been configured with respect to the unlicensed band cell in theterminal that performs UCI (e.g., non-periodic CSI, HARQ-ACK, schedulingrequest, or periodic CSI and HARQ-ACK) transmission in subframe n willbe described. If it is determined that only the channel for the PUCCHcell is in an idle state after the channel sensing operation for thePUCCH cell and the PUSCH cell, the terminal may transmit the whole or apart of the UCI information that excludes the non-periodic CSIinformation through the PUCCH that is configured in the PUCCH cell. Ifit is determined that the channel for the PUCCH cell is not in an idlestate, but the PUSCH transmission cell for the non-periodic CSItransmission is in an idle state after the channel sensing operation forthe PUCCH cell and the PUSCH cell, the terminal may transmit only thenon-periodic CSI information through the PUSCH that is configured in thePUSCH transmission cell, and may transmit the whole or a part of theremaining UCI information that excludes the scheduling requestinformation through the PUSCH that is configured in the PUSCHtransmission cell.

Next, a case where PUSCH transmission for the cell that operates in atleast one licensed band among the cells that are included in the group(the second PUCCH group) for the configured unlicensed band PUCCHtransmission cell has been configured in the terminal that performs UCItransmission in subframe n will be described. The UCI may be transmittedfrom one of the licensed band cells in which the PUSCH transmission hasbeen configured, for example, from a cell having the smallest SCellIndexamong the licensed band cells in which the PUSCH transmission has beenconfigured. More detailed operation thereof is as follows.

Next, a case where PUSCH transmission for the cell that operates in atleast one licensed band among the cells that are included in the group(the second PUCCH group) for the configured unlicensed band PUCCHtransmission cell has been configured in the terminal that performs UCI(e.g., periodic CSI, HARQ-ACK, scheduling request, periodic CSI andHARQ-ACK, or HARQ-ACK and scheduling request) transmission in subframe nwill be described. Regardless of determination of whether the unlicensedband cell is an idle channel, the terminal may transmit the whole or apart of the UCI information that excludes at least the schedulingrequest that is included in the PUSCH that is configured in the cellhaving the smallest SCellIndex among the licensed band cells in whichthe PUSCH transmission has been configured. If it is determined thatonly the channel for the PUCCH cell among the above-described cells isin an idle state after the channel sensing operation for the PUCCH celland the PUSCH cell, and the PUSCH transmission in the PUCCH cell has notbeen configured, the terminal may transmit a part (e.g., periodic CSIinformation) of the UCI information that is included in the PUSCH thatis configured in the cell having the smallest SCellIndex among thelicensed band cells in which the PUSCH transmission has been configured,and may transmit the UCI information excluding the information that hasbeen transmitted to the licensed band cells (e.g., HARQ-ACK, schedulingrequest, or HARQ-ACK and scheduling request) through the PUCCH that isconfigured in the PUCCH cell. In this case, the kind of the UCI that istransmitted through the licensed band cell and the PUCCH cell may bemerely exemplary, and it is also possible to transmit other UCI that isdifferent from that as described above to the licensed band cell and thePUCCH cell.

If it is determined that only the channel for the PUCCH cell among theabove-described cells is in an idle state after the channel sensingoperation for the PUCCH cell and the PUSCH cell, and the PUSCHtransmission in the PUCCH cell has been configured, the terminal maytransmit a part (e.g., periodic CSI information) of the UCI informationthat is included in the PUSCH that is configured in the cell having thesmallest SCellIndex among the licensed band cells in which the PUSCHtransmission has been configured, and may transmit the UCI informationexcluding the information that has been transmitted to the licensed bandcells (e.g., HARQ-ACK, scheduling request, or HARQ-ACK and schedulingrequest) through the PUCCH that is configured in the PUCCH cell.Further, the terminal may transmit a part (e.g., periodic CSIinformation) of the UCI information that is included in the PUSCHtransmission that is configured in the PUCCH cell, and may transmit theUCI information excluding the information that is included in the PUSCHtransmission to be transmitted (e.g., HARQ-ACK, scheduling request, orHARQ-ACK and scheduling request) through the PUCCH that is configured inthe PUCCH cell. In this case, it is also possible to transmit the UCIinformation that is entirely included in the PUSCH that is configuredfor the PUCCH cell. If the transmission of the PUSCH that is configuredin the PUCCH cell is signal transmission for an initial access of theterminal, the UCI is not transmitted. In this case, the kind of the UCIthat is transmitted through the licensed band cell and the PUCCH cellmay be merely exemplary, and it is also possible to transmit other UCIthat is different from that as described above to the licensed band celland the PUCCH cell.

Next, a case where PUSCH transmission for the non-periodic CSItransmission in subframe n for the cells that are included in the group(the second PUCCH group) for configured unlicensed band PUCCHtransmission cell has been configured with respect to the licensed bandcell in the terminal that performs UCI (e.g., non-periodic CSI,HARQ-ACK, scheduling request, or periodic CSI and HARQ-ACK) transmissionin subframe n will be described. If it is determined that the channelfor the PUCCH cell is in an idle state after the channel sensingoperation for the PUCCH cell and the PUSCH cell, the terminal maytransmit the UCI information excluding the non-periodic CSI through thePUCCH that is configured in the PUCCH cell, and may transmit thenon-periodic CSI information that is included in the PUSCH transmissionin the licensed band that is configured for the non-periodic CSIinformation transmission. If it is determined that the channel for thePUCCH cell is not in an idle state after the channel sensing operationfor the PUCCH cell and the PUSCH cell, the terminal may transmit the UCIinformation excluding the scheduling request that is included in thePUSCH transmission in the licensed band that is configured for thenon-periodic CSI information transmission. Further, regardless ofdetermination of whether the unlicensed band cell is an idle channel,the terminal may transmit the UCI information that is included in thePUSCH that is configured in the PUSCH transmission cell for the licensedband that is configured for a non-periodic CSI information report and inthe cell having the smallest SCellIndex among the licensed band cells inwhich the PUSCH transmission has been configured.

Next, a case where PUSCH transmission for the non-periodic CSItransmission in subframe n for the cells that are included in the group(the second PUCCH group) for configured unlicensed band PUCCHtransmission cell has been configured with respect to the unlicensedband cell, and PUSCH transmission for at least one licensed band hasbeen configured in the terminal that performs UCI (e.g., non-periodicCSI, HARQ-ACK, scheduling request, or periodic CSI and HARQ-ACK)transmission in subframe n will be described. If it is determined thatonly the channel for the PUCCH cell is in an idle state after thechannel sensing operation for the PUCCH cell and the PUSCH cell, and thePUSCH transmission cell that is configured for the non-periodic CSItransmission is equal to the PUCCH transmission cell, the terminal maytransmit the UCI information excluding the non-periodic CSI through thePUCCH that is configured in the PUCCH cell, and may transmit thenon-periodic CSI information through the PUSCH transmission cell that isconfigured for the non-periodic CSI information transmission. In thiscase, if it is determined that the PUSCH transmission cell that isconfigured for the non-periodic CSI transmission is different from thePUCCH transmission cell and the PUSCH cell is not in an idle state, theterminal may transmit the UCI information excluding the non-periodic CSIinformation through the PUCCH that is configured in the PUCCH cell, maynot transmit the non-periodic CSI information, or may transmit the UCIthat is included in the cell having the smallest SCellIndex among thelicensed band cells in which the PUSCH has been configured.

Embodiment 3

Hereinafter, in the present disclosure, it is assumed that in a terminalin which one or more PUCCH transmission cells have been configured andPUCCH-PUSCH simultaneous transmission has not been configured, at leastone of the configured PUCCH transmission cells is configured as a cellthat operates in an unlicensed band, and UCI (e.g., information on atleast one of periodic CSI, HARQ-ACK, scheduling request, periodic CSIand HARQ-ACK, HARQ-ACK and scheduling request, non-periodic CSI andHARQ-ACK, non-periodic CSI and scheduling request, or non-periodic CSIand HARQ-ACK and scheduling request) transmission for a PUCCH group (orthe second PUCCH group) that is composed of cells that perform PUCCHtransmission to the PUCCH transmission cell (hereinafter referred to as“PUCCH transmission cell”) that operates in the configured unlicensedband is required in subframe n. A UCI transmission method that isproposed in the present disclosure will be described as follows. In thiscase, the method that is proposed in this embodiment can be applied toall embodiments that are described in the present disclosure withoutbeing limited to this embodiment. In this case, if the periodic CSI andnon-periodic CSI information reports occur simultaneously, the terminalmay give preference to the non-periodic CSI information report withoutreporting the periodic CSI information, or may give preference to theperiodic CSI without reporting the non-periodic CSI information.

A case where PUSCH transmission for the cell that operates in at leastone unlicensed band among the cells that are included in the group (thesecond PUCCH group) for the configured unlicensed band PUCCHtransmission cell has been configured will be described. If it isdetermined that an unlicensed band channel of at least one of theabove-described cells is in an idle state after the channel sensingoperation for the PUCCH cell and PUSCH cell, a UCI transmission methodof the terminal is determined in accordance with the cell in which it isdetermined that the unlicensed band channel is an idle channel, the kindof the UCI, and whether to transmit the PUSCH, and thus the presentdisclosure proposes a correct UCI transmission method of the terminal inthe above-described case.

For example, if the PUSCH transmission has not been configured in thecell that operates in the licensed band among the cells that areincluded in the group for a unlicensed band PUCCH transmission cell at aUCI information transmission time, the terminal may or may not transmitthe UCI information in accordance with the result of the channel sensingoperation in the reference cell on the basis of one of the PUCCH celland the unlicensed band cell in which the PUSCH transmission has beenconfigured. As another example, if the PUSCH transmission has beenconfigured in the cell that operates in at least one licensed band amongthe cells that are included in the group for the unlicensed band PUCCHtransmission cell at the UCI information transmission time, the terminaltransmits the UCI information that is included in the cell having thesmallest SCellIndex among the licensed band cells. Hereinafter, theabove-described case will be described in more detail.

Next, a case where the PUSCH transmission in subframe n has not beenconfigured for the cells that are included in the group (the secondPUCCH group) for the configured unlicensed band PUCCH transmission cellsin the terminal that performs UCI (e.g., periodic CSI, HARQ-ACK,scheduling request, periodic CSI and HARQ-ACK, or HARQ-ACK andscheduling request) transmission in subframe n will be described. If itis determined that the channel for the PUCCH cell is in an idle stateafter the channel sensing operation for the PUCCH cell, the terminal maytransmit the UCI through the PUCCH that is configured in the PUCCH cell.If it is determined that the channel for the PUCCH cell among theabove-described cells is not in an idle state after the channel sensingoperation for the PUCCH cell, the terminal may not transmit the UCIinformation to the PUCCH cell, or may transfer the UCI informationthrough the PUCCH of PCell.

Next, a case where PUSCH transmission in subframe n for the cell thatoperates in the licensed band among the cells that are included in thegroup (the second PUCCH group) for the configured unlicensed band PUCCHtransmission cell has not been configured, but PUSCH transmission forthe cell that operates in at least one unlicensed band has beenconfigured in the terminal that performs UCI (e.g., periodic CSI,HARQ-ACK, scheduling request, or periodic CSI and HARQ-ACK) transmissionin subframe n will be described. If it is determined that only thechannel for the PUCCH cell among the above-described cells is in an idlestate after the channel sensing operation for the PUCCH cell and thePUSCH cell, and the PUSCH transmission in the PUCCH channel has not beenconfigured, the terminal may transmit the UCI information through thePUCCH that is configured in the PUCCH cell. If it is determined that allthe channels for the above-described cells are not in an idle stateafter the channel sensing operation for the PUCCH cell and the PUSCHcell, the terminal may not transmit the UCI information, or may transmitthe UCI information through the PUCCH of PCell.

Further, if only PUCCH cell and PUSCH cell transmission has beenconfigured in the unlicensed band as described above, the terminal mayor may not transmit the UCI in accordance with the result of the channelsensing operation in a reference cell on the basis of one of the PUCCHcell and the PUSCH cell. For example, in the case of configuration onthe basis of the PUCCH transmission cell, the terminal may transmit theUCI through the PUCCH that is configured in the PUCCH transmission cellif the channel for the PUCCH transmission cell is in an idle stateregardless of the result of the channel sensing operation of the PUSCHtransmission cell. Further, if the PUSCH cell is configured as thereference, the terminal may transmit the periodic CSI, HARQ-ACK, orperiodic CSI and HARQ-ACK information that is included in the configuredPUSCH transmission. Further, the terminal may transmit the UCI throughthe PUCCH of PCell regardless of the result of the channel sensingoperation in the PUCCH cell and the PUSCH cell of the unlicensed band.

Next, a case where PUSCH transmission in subframe n for the cell thatoperates in the licensed band among the cells that are included in thegroup (the second PUCCH group) for the configured unlicensed band PUCCHtransmission cell has not been configured, but PUSCH transmission forthe cell that operates in at least one unlicensed band has beenconfigured in the terminal that performs UCI (e.g., periodic CSI,HARQ-ACK, scheduling request, or periodic CSI and HARQ-ACK) transmissionin subframe n will be described. If it is determined that only thechannel for the PUCCH cell among the above-described cells is in an idlestate after the channel sensing operation for the PUCCH cell and thePUSCH cell, and the PUSCH transmission in the PUCCH channel has beenconfigured, the terminal may transmit at least the periodic CSI,HARQ-ACK, or periodic CSI and HARQ-ACK information of the UCI that isincluded in the PUSCH that is configured in the PUCCH cell. If thetransmission of the PUSCH that is configured in the PUCCH cell is signaltransmission for an initial access of the terminal, the UCI is nottransmitted. If it is determined that the channels for the cells are notin an idle state after the channel sensing operation for the PUCCH celland the PUSCH cell, the terminal may not transmit the UCI information,or may transmit the UCI information through the PUCCH of PCell.

A case where PUSCH transmission in subframe n for the cell that operatesin the licensed band among the cells that are included in the group (thesecond PUCCH group) for the configured unlicensed band PUCCHtransmission cell has not been configured, but PUSCH transmission forthe cell that operates in at least one unlicensed band has beenconfigured in the terminal that performs UCI (e.g., periodic CSI,HARQ-ACK, scheduling request, or periodic CSI and HARQ-ACK) transmissionin subframe n will be described. If it is determined that the channelfor the PUCCH cell among the above-described cells is not in an idlestate after the channel sensing operation for the PUCCH cell and thePUSCH cell, but the channel for at least one PUSCH transmission cell isin an idle state, the terminal may transmit at least the periodic CSI,HARQ-ACK, or periodic CSI and HARQ-ACK information of the UCIinformation that is included in the PUSCH that is configured in the cellhaving the smallest SCellIndex among the cells in which it is determinedthat the channel is in the idle state, the cell in which it is mostquickly determined that the channel is in the idle state, or the cellhaving the smallest SCellIndex among the PUSCH cells in which it isdetermined that the channel is in the idle state.

A case where PUSCH transmission in subframe n for the cell that operatesin the licensed band among the cells that are included in the group (thesecond PUCCH group) for the configured unlicensed band PUCCHtransmission cell has not been configured, but PUSCH transmission forthe cell that operates in at least one unlicensed band has beenconfigured in the terminal that performs UCI (e.g., periodic CSI,HARQ-ACK, scheduling request, or periodic CSI and HARQ-ACK) transmissionin subframe n will be described. If it is determined that the channelfor at least one PUSCH transmission cell including the PUCCH cell amongthe above-described cells is in an idle state after the channel sensingoperation for the PUCCH cell and the PUSCH cell, and the PUSCHtransmission in the PUCCH transmission cell has not been configured, theterminal may transmit at least the periodic CSI, HARQ-ACK, or periodicCSI and HARQ-ACK information of the UCI information that is included inthe PUSCH that is configured in the cell having the smallest SCellIndexamong the PUSCH cells in which it is determined that the channel is inthe idle state, the cell in which it is most quickly determined that thechannel is in the idle state, or the cell having the smallest SCellIndexamong the cells in which it is determined that the channel is in theidle state.

A case where PUSCH transmission in subframe n for the cell that operatesin the licensed band among the cells that are included in the group (thesecond PUCCH group) for the configured unlicensed band PUCCHtransmission cell has not been configured, but PUSCH transmission forthe cell that operates in at least one unlicensed band has beenconfigured in the terminal that performs UCI (e.g., periodic CSI,HARQ-ACK, scheduling request, or periodic CSI and HARQ-ACK) transmissionin subframe n will be described. If it is determined that the channelfor at least one PUSCH transmission cell including the PUCCH cell amongthe above-described cells is in an idle state after the channel sensingoperation for the PUCCH cell and the PUSCH cell, and the PUSCHtransmission in the PUCCH transmission cell has been configured, theterminal may transmit at least the periodic CSI, HARQ-ACK, or periodicCSI and HARQ-ACK information of the UCI information that is included inthe PUSCH that is configured in the PUCCH cell, or may transmit at leastthe periodic CSI, HARQ-ACK, or periodic CSI and HARQ-ACK information ofthe UCI information that is included in the PUSCH that is configured inthe cell having the smallest SCellIndex among the PUSCH cells in whichit is determined that the channel is in the idle state, the cell inwhich it is most quickly determined that the channel is in the idlestate, or the cell having the smallest SCellIndex among the cells inwhich it is most quickly determined that the channel is in the idlestate.

Next, a case where PUSCH transmission for non-periodic CSI transmissionin subframe n for the cells that are included in the group (the secondPUCCH group) for the configured unlicensed band PUCCH transmission cellhas been configured with respect to the unlicensed band cell in theterminal that performs UCI (e.g., non-periodic CSI, HARQ-ACK, schedulingrequest, or HARQ-ACK and scheduling request) transmission in subframe nwill be described. If it is determined that only the channel for thePUCCH cell is in an idle state after the channel sensing operation forthe PUCCH cell and the PUSCH cell, the terminal may transmit the UCIinformation that excludes the non-periodic CSI information through thePUCCH that is configured in the PUCCH cell. If it is determined that thechannel for the PUCCH cell is not in an idle state, but the PUSCHtransmission cell for the non-periodic CSI transmission is in an idlestate after the channel sensing operation for the PUCCH cell and thePUSCH cell, the terminal may transmit at least the non-periodic CSI ornon-periodic CSI and HARQ-ACK information through the PUSCH that isconfigured in the PUSCH transmission cell. If it is determined that thePUCCH cell and the PUSCH transmission cell for the non-periodic CSItransmission are in an idle state after the channel sensing operationfor the PUCCH cell and the PUSCH cell, the terminal may transmit thenon-periodic CSI or non-periodic CSI and HARQ-ACK in the PUSCHtransmission cell for the non-periodic CSI transmission. If it isdetermined that both the PUCCH cell and the PUSCH transmission cell forthe non-periodic CSI transmission are not in an idle state after thechannel sensing operation for the PUCCH cell and the PUSCH cell, theterminal may not transmit the UCI information, or may transmit theremaining UCI information that excludes the non-periodic CSI informationthrough the PUCCH of PCell.

Next, a case where PUSCH transmission for the cell that operates in atleast one licensed band among the cells that are included in the group(the second PUCCH group) for the configured unlicensed band PUCCHtransmission cell has been configured in the terminal that performs UCItransmission in subframe n will be described. In this case, the UCI maybe transmitted from one of licensed band cells in which the PUSCHtransmission has been configured, for example, from a cell having thesmallest SCellIndex among the licensed band cells in which the PUSCHtransmission has been configured. More detailed operation thereof is asfollows.

A case where PUSCH transmission for the cell that operates in at leastone licensed band among the cells that are included in the group (thesecond PUCCH group) for the configured unlicensed band PUCCHtransmission cell has been configured in the terminal that performs UCI(e.g., periodic CSI, HARQ-ACK, scheduling request, or periodic CSI andHARQ-ACK) transmission in subframe n will be described. If it isdetermined that only the channel for the PUCCH cell among theabove-described cells is in an idle state after the channel sensingoperation for the PUCCH cell and the PUSCH cell, and the PUSCHtransmission in the PUCCH cell has not been configured, the terminal maytransmit the UCI information through the PUCCH that is configured in thePUCCH cell, or may transmit at least periodic CSI or HARQ-ACK periodicCSI and HARQ-ACK information of the UCI information that is included inthe PUSCH that is configured in the cell having the smallest SCellIndexamong the licensed band cells in which the PUSCH transmission has beenconfigured. In this case, if the PUSCH transmission for the cell thatoperates in at least one licensed band is configured, the terminal maytransmit at least periodic CSI or HARQ-ACK periodic CSI and HARQ-ACKinformation of the UCI information that is included in the PUSCH that isconfigured in the cell having the smallest SCellIndex among the licensedband cells in which the PUSCH transmission has been configuredregardless of determination of whether the unlicensed band cell is anidle channel.

A case where PUSCH transmission in subframe n for the cells that areincluded in the group (the second PUCCH group) for the configuredunlicensed band PUCCH transmission cell has been configured in theterminal that performs UCI (e.g., periodic CSI, HARQ-ACK, schedulingrequest, or periodic CSI and HARQ-ACK) transmission in subframe n willbe described. If it is determined that only the channel for the PUCCHcell among the above-described cells is in an idle state after thechannel sensing operation for the PUCCH cell and the PUSCH cell, and thePUSCH transmission in the PUCCH cell has been configured, the terminalmay transmit at least periodic CSI information or HARQ-ACK periodic CSIand HARQ-ACK information of the UCI information that is included in thePUSCH that is configured in the PUCCH cell. Further, regardless ofdetermination of whether the unlicensed band cell is an idle channel,the terminal may transmit at least periodic CSI information, HARQ-ACK,or periodic CSI and HARQ-ACK information of the UCI information that isincluded in the PUSCH that is configured in the cell having the smallestSCellIndex among the licensed band cells in which the PUSCH transmissionhas been configured. If the PUSCH transmission that is configured in thePUCCH cell is signal transmission for an initial access of the terminal,the UCI is not transmitted.

Next, a case where PUSCH transmission for the non-periodic CSItransmission in subframe n for the cells that are included in the group(the second PUCCH group) for the configured unlicensed band PUCCHtransmission cell has been configured in the terminal that performs UCI(e.g., non-periodic CSI, HARQ-ACK, scheduling request, or periodic CSIand HARQ-ACK) transmission in subframe n will be described. The terminalmay transmit the non-periodic CSI or non-periodic CSI and HARQ-ACKinformation of the UCI information that is included in the PUSCHtransmission in the licensed band regardless of the result of thechannel sensing operation for the PUCCH cell. In this case, the UCI thatexcludes the non-periodic CSI and HARQ-ACK information may not betransmitted.

Next, a case where PUSCH transmission for the non-periodic CSItransmission in subframe n for the cells that are included in the group(the second PUCCH group) for the configured unlicensed band PUCCHtransmission cell has been configured with respect to the unlicensedband cell, and PUSCH transmission in at least one licensed band has beenconfigured in the terminal that performs UCI (e.g., non-periodic CSI,HARQ-ACK, scheduling request, or periodic CSI and HARQ-ACK) transmissionin subframe n will be described. The terminal may transmit at leastHARQ-ACK information of the UCI information that is included in thePUSCH transmission in the cell having the smallest SCellIndex among thePUSCH transmission cells in the licensed band regardless of the resultof the channel sensing operation for the PUCCH cell. In this case, theUCI that excludes the HARQ-ACK information may not be transmitted.

FIG. 6 is a flowchart illustrating a base station operation method forreceiving UCI information according to an embodiment of the presentdisclosure.

At operation 600, a base station may configure one or more serving cellsin accordance with capabilities of the base station and a terminal. Inthis case, the configured serving cell may include a cell that operatesin an unlicensed band in accordance with the capabilities of the basestation and the terminal, and the number of serving cells that can beconfigured may differ also in accordance with the capabilities of thebase station and the terminal. At operation 610, the base station may ormay not configure PUCCH and PUSCH simultaneous transmission to theterminal in accordance with the determination of the base station andwhether the PUCCH and PUSCH simultaneous transmission of the terminalcan be performed. Referring to FIG. 6, it is assumed that the basestation does not configure the PUCCH and PUSCH simultaneous transmissionto the terminal. However, various embodiments of the present disclosurecan be applied even in the case where the base station configures thePUCCH and PUSCH simultaneous transmission to the terminal. At operation620, if the base station requests/configures non-periodic CSIinformation transmission with respect to the terminal in subframe n-K,or the terminal configures transmission of UCI information, such asperiodic CSI, HARQ-ACK, or SR, in subframe n, at least one of UCIinformation configuration of the terminal and a cell in which the UCI istransmitted may be differently configured depending on whether totransmit PUSCH in at least one of PCell in subframe n and SCell thatoperates in a licensed band or an unlicensed band. Referring to FIG. 6,the base station operates to request the terminal to report non-periodicCSI information in subframe n-K, and to transmit the non-periodic CSIinformation through the PUSCH in the licensed band in subframe n.However, various embodiments of the present disclosure as describedabove can be applied even in the case where the base station configuresonly transmission of PCell or PUSCH in the unlicensed band to theterminal. At operation 630, the base station determines whether toconfigure the PUSCH transmission to the terminal in at least onelicensed band in subframe n. Accordingly, the terminal transmits the UCIinformation to the base station through the SCell having the smallestSCellIndex among SCells in which the PUSCH transmission has beenconfigured or the configured licensed band PUSCH, and the base stationreceives a part or the whole of the UCI information of the terminalthrough the SCell at operation 640. In this case, if there is not PUSCHtransmission configuration in the licensed band in subframe n, theterminal transmits a part or the whole of the UCI information of theterminal in the cell in which the PUCCH transmission has beenconfigured, and the base station receives the part or the whole of theUCI information of the terminal through the PUCCH at operation 650.

FIG. 7 is a flowchart illustrating a terminal operation method fortransmitting UCI information according to an embodiment of the presentdisclosure.

At operation 700, the terminal may receive a request for configurationof one or more serving cells from the base station in accordance withcapabilities of the base station and the terminal. In this case, theconfigured serving cell may include a cell that operates in theunlicensed band in accordance with the capabilities of the base stationand the terminal, and the number of serving cells that can be configuredmay differ also in accordance with the capabilities of the base stationand the terminal. At operation 710, the terminal may receiveconfiguration on whether PUCCH and PUSCH simultaneous transmission canbe performed from the base station, and operates in accordance with thereceived configuration. Referring to FIG. 7, it is assumed that the basestation does not configure the PUCCH and PUSCH simultaneous transmissionto the terminal. However, various embodiments of the present disclosurecan be applied even in the case where the base station configures thePUCCH and PUSCH simultaneous transmission to the terminal. At operation720, if the base station requests/configures non-periodic CSIinformation transmission with respect to the terminal in subframe n-K,or the terminal configures transmission of the UCI information, such asperiodic CSI, HARQ-ACK, or SR, in subframe n, at least one of UCIinformation configuration of the terminal and a cell in which the UCI istransmitted may be differently configured depending on whether totransmit the PUSCH in at least one of PCell in subframe n and SCell thatoperates in a licensed band or an unlicensed band. Referring to FIG. 7,the base station operates to request the terminal to report non-periodicCSI information in subframe n-K, and to transmit the non-periodic CSIinformation through the PUSCH in the licensed band in subframe n.However, various embodiments of the present disclosure as describedabove can be applied even in the case where the base station configuresonly transmission of PCell or PUSCH in the unlicensed band to theterminal. At operation 730, the terminal determines whether to configurethe PUSCH transmission from the base station to the terminal in at leastone licensed band in subframe n. Accordingly, the terminal transmits theUCI information to the base station through the SCell having thesmallest SCellIndex among SCells in which the configured licensed bandPUSCH or SCell has been configured at operation 740. In this case, ifthere is not PUSCH transmission configuration in the licensed band insubframe n, the terminal transmits a part or the whole of the UCIinformation of the terminal in the cell in which the PUCCH transmissionhas been configured through the PUCCH at operation 750.

If the terminal transmits the corresponding UCI that is included in theSCell having the smallest SCellIndex among the SCells in which the PUSCHtransmission has been configured after performing channel sensingoperation for the SCell in which uplink transmission is possible, theSCell having the smallest SCellIndex in which the UCI is included may bechanged in accordance with the result of the channel sensing operation.In this case, between channel sensing operation end time for the Scelland PUSCH transmission start time for the Scell, only transition timefor changing a reception operation to a transmission operation exists,which is 0 or very short time, and thus it may be difficult toregenerate the signal to be transmitted on the PUSCH so that thatterminal makes the UCI included in uplink data, Accordingly, in the caseof transmitting only the PUSCH with respect to the respective SCells inwhich uplink transmission has been configured, the terminal may generatein advance the uplink transmission signal for transmitting the UCI thatis included in the PUSCH, Thereafter, the terminal may perform thechannel sensing operation for the SCells, perform transmission of theUCI that is included in the PUSCH in the Scell having the smallestSCellIndex among SCells that are determined as idle channels, andperform PUSCH transmission that includes only the uplink datainformation without control information in the remaining SCells.

In this case, the base station does not know what Scell the UCI of theterminal is transmitted through, In other words, since the base stationdoes not know the result of the channel sensing operation of theterminal, it should find out whether the UCI is included with respect toall SCells in which the uplink transmission has been configured throughthe terminal, In other words, the base station should decode the uplinksignal on the assumption that the UCI is included in the Scell PUSCHtransmission and should decode the uplink signal on the assumption thatthe UCI is not included in the SCell PUSCH transmission with respect toall the SCells in which the uplink transmission has been configuredthrough the base station, In this case, in order to operate the basestation more efficiently, the base station may first detect whether theuplink signal of the corresponding terminal has been transmitted in theorder of SCell having the smallest SCellIndex among all SCells in whichthe uplink transmission has been configured through the terminal, Forexample, whether the uplink signal of the terminal has been transmittedcan be determined using the existence/nonexistence of DMRS for theuplink data channel of the terminal or the level of a received powerthat is measured from frequency/time resources in which the uplinktransmission has been configured.

Specifically, the base station determines whether the uplinktransmission of the terminal has been performed in the Scell having thesmallest SCellIndex among all the SCells in which the uplinktransmission has been configured through the terminal, If it isdetermined that the terminal has not performed the uplink transmissionin the Scell having the smallest SCellIndex, the base station determineswhether the uplink transmission of the terminal has been performed withrespect to the SCell having the next small SCellIndex, If the uplinktransmission of the terminal is detected in the Scell having thesmallest SCellIndex, the base station may perform decoding on theassumption that the UCI is included in the PUSCH transmission in theScell.

If it is determined that the UCI is included in the SCell having thesmallest SCellIndex, the base station may perform decoding of thecorresponding PUSCH on the assumption that the UCI information is notincluded in other SCells, In other words, if it is determined that theUCI information is included in one of the above-described SCells, thebase station assumes that the SCellIndex is not transmitted from othercells, and decodes only the PUSCH information without considering a casewhere the UCI information that is included in the PUSCH is transmittedfor data decoding of the corresponding SCells.

FIG. 8 is a diagram illustrating a base station device according toembodiments of the present disclosure.

A receiver 830 of a base station 800 may receive signals from anotherbase station or a terminal and may measure channels from the basestation or the terminal, Further, the receiver may sense unlicensed bandchannels using setting values for the channel sensing operation that isconfigured through a base station controller 810, Further, whenoccupying the unlicensed band, the receiver may determine thetransmission power that can be transmitted in the unlicensed band, Thebase station controller 810 may determine whether the unlicensed band isin an idle state using information on the unlicensed band that is sensedby the receiver 830, If the unlicensed band is determined to be in anidle state, the base station controller 810 may transmit a signal forchannel occupation in a transmitter 820 of the base station, controlchannel and data channel information for a specific terminal, orconfiguration information on the transmission power of an LAA cell,Further, the base station controller 810 may control the receiver 830 tocorrectly receive the UCI transmission of the terminal through which atleast one of the UCI information, UCI transmission cell, and UCItransmission channel may be changed in accordance with the PUSCHtransmission configuration in the licensed band or unlicensed band atUCI information transmission time of the terminal.

If the determined unlicensed band is not in an idle state, the basestation controller 810 may be configured to continuously perform thechannel sensing operation through the base station receiver 830, Thebase station controller 810 may determine a part or the whole ofparameters which include control channel transmission parameterconfiguration, such as PDCCH/EPDCCH for a specific terminal, variouskinds of reference signal transmission parameter configuration,PDSCH/DPDSCH scheduling information, CRS, CSI-RS, DRS, and PDSCH thatare required for configuration or transfer between the base station andthe terminal, Further, the base station controller 810 may configurecells that operate in one or more of different bands, that is, thelicensed band and the unlicensed band, in accordance with thecapabilities of the base station and the terminal to the terminal, andmay configure PUCCH and PUSCH simultaneous transmission.

FIG. 9 is a diagram illustrating a terminal device according toembodiments of the present disclosure.

Referring to FIG. 9, a controller 910 of a terminal 900 controls areceiver 930 to receive configuration information between the basestation and the terminal for signal transmission in a licensed band andan unlicensed band from the base station, and uses the unlicensed bandin accordance with the received configuration values, Further, thecontroller may receive a first signal transmittable time, a secondsignal transmittable time, and the signal configuration from the basestation through the receiver 930 of the terminal, or may receiveconfiguration of the channel occupation period of the LAA cell ordetermination methods for the last partial subframe, Further, theterminal 900 may receive configuration information on the transmissionpower in the channel occupation period of the LAA cell from the basestation through the receiver 930, The controller 910 may acquire statusinformation of the corresponding unlicensed band suing at least one of aconfiguration value for determining whether scheduling can be performedin a subframe that performs the channel sensing operation that isconfigured by the base station and is received through the receiver 930,a configuration value for a signal that is transmitted to a channeloccupation start symbol of the base station, unlicensed band statusinformation that can be transmitted by the base station to the terminalusing the licensed band or another unlicensed band, and transmissionpower configuration information in the channel occupation period of theLAA cell, and may receive a signal from the unlicensed band, Further,the controller 910 may determine whether to occupy the channel of theLAA cell using the second signal transmission that is received anddetected from the LAA cell, Further, the controller 910 may determinethe length of the last partial subframe of the LAA cell using at leastone of the first or second signal transmittable time that is configuredfrom the LAA cell and the channel occupation period of the LAA cell,Further, the controller 910 may determine the result of receiving a datasignal that is received from the base station, and may report the resultof data reception to the base station through the transmitter 920,Further, the controller 910 may control the receiver 930 to receive acorrect signal using the transmission power for the channel occupationperiod of the LAA cell that is received from the LAA cell, Further, thecontroller 910 or the receiver 930 may include a decoder that receivesPDCCH/EPDCCH and PDSCH and decodes the PDSCH, Further, in accordancewith the PUSCH transmission configuration in the licensed band or theunlicensed band at the UCI information transmission time of theterminal, the transmitter may correctly transmit the UCI transmission ofthe terminal through changing of at least one of the UCI information,UCI transmission cell, and a UCI transmission channel under the controlof the controller 910.

Although the present disclosure has been described with an exemplaryembodiment, various changes and modifications may be suggested to oneskilled in the art. It is intended that the present disclosure encompasssuch changes and modifications as fall within the scope of the appendedclaims.

What is claimed is:
 1. A method performed by a base station in acommunication system, the method comprising: receiving, from a terminal,first control information on a physical uplink shared channel (PUSCH) ofa secondary cell (SCell) other than an unlicensed band SCell and secondcontrol information on a physical uplink control channel (PUCCH), incase that the terminal is configured with more than one serving cell anda simultaneous transmission of the PUSCH and the PUCCH, and the PUSCH isnot transmitted on a primary cell (PCell) and the PUSCH is transmittedon the SCell, wherein the first control information is periodic channelstate information (CSI) and the second control information is a hybridautomatic repeat request (HARQ) acknowledgement (ACK).
 2. The method ofclaim 1, wherein the first control information and the second controlinformation are received on the PUCCH, in case that the PUSCH istransmitted only on SCell associated with an unlicensed band.
 3. Themethod of claim 2, wherein the first control information and the secondcontrol information are received on a same subframe without the PUSCH.4. The method of claim 1, wherein the first control information isreceived on the PUSCH of the SCell other than an unlicensed band with asmallest SCell index.
 5. A method performed by a terminal in acommunication system, the method comprising: transmitting, to a basestation, first control information on a physical uplink shared channel(PUSCH) of an secondary cell (SCell) other than an unlicensed band SCelland second control information on a physical uplink control channel(PUCCH), in case that the terminal is configured with more than oneserving cell and a simultaneous transmission of the PUSCH and the PUCCH,and the PUSCH is not transmitted on a primary cell (PCell) and the PUSCHis transmitted on the SCell, wherein the first control information isperiodic channel state information (CSI) and the second controlinformation is a hybrid automatic repeat request (HARQ) acknowledgement(ACK).
 6. The method of claim 5, wherein the first control informationand the second control information are transmitted on the PUCCH, in casethat the PUSCH is transmitted only on SCell associated with anunlicensed band.
 7. The method of claim 6, wherein the first controlinformation and the second control information are transmitted on a samesubframe without the PUSCH.
 8. The method of claim 5, wherein the firstcontrol information is transmitted on the PUSCH of the SCell other thanan unlicensed band with a smallest SCell index.
 9. A base station in acommunication system, the base station comprising: a transceiver; and acontroller configured to receive, from a terminal via the transceiver,first control information on a physical uplink shared channel (PUSCH) ofan secondary cell (SCell) other than an unlicensed band SCell and secondcontrol information on a physical uplink control channel (PUCCH), incase that the terminal is configured with more than one serving cell anda simultaneous transmission of the PUSCH and the PUCCH, and the PUSCH isnot transmitted on a primary cell (PCell) and the PUSCH is transmittedon the SCell, wherein the first control information is periodic channelstate information (CSI) and the second control information is a hybridautomatic repeat request (HARQ) acknowledgement (ACK).
 10. The basestation of claim 9, wherein the first control information and the secondcontrol information are received on the PUCCH, in case that the PUSCH istransmitted only on SCell associated with an unlicensed band.
 11. Thebase station of claim 10, wherein the first control information and thesecond control information are received on a same subframe without thePUSCH.
 12. The base station of claim 11, wherein the first controlinformation is received on the PUSCH of the SCell other than anunlicensed band with a smallest SCell index.
 13. A terminal in acommunication system, the terminal comprising: a transceiver; and acontroller configured to transmit, to a base station via thetransceiver, first control information on a physical uplink sharedchannel (PUSCH) of an secondary cell (SCell) other than an unlicensedband SCell and second control information on a physical uplink controlchannel (PUCCH), in case that the terminal is configured with more thanone serving cell and a simultaneous transmission of the PUSCH and thePUCCH, and the PUSCH is not transmitted on a primary cell (PCell) andthe PUSCH is transmitted on the SCell, wherein the first controlinformation is periodic channel state information (CSI) and the secondcontrol information is a hybrid automatic repeat request (HARQ)acknowledgement (ACK).
 14. The terminal of claim 13, wherein the firstcontrol information and the second control information are transmittedon the PUCCH, in case that the PUSCH is transmitted only on SCellassociated with an unlicensed band.
 15. The terminal of claim 14,wherein the first control information and the second control informationare transmitted on a same subframe without the PUSCH.
 16. The terminalof claim 13, wherein the first control information is transmitted on thePUSCH of the SCell other than an unlicensed band with a smallest SCellindex.